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Climate, lactation, and treatment factors influence faecal shedding of Escherichia coli O157 pathotypes in dairy cows

Published online by Cambridge University Press:  16 September 2016

C. STENKAMP-STRAHM ,
C. McCONNEL ,
S. RAO ,
R. MAGNUSON ,
D. R. HYATT  and
L. LINKE
C. STENKAMP-STRAHM*
Affiliation:
Colorado State University, Department of Clinical Sciences, Animal Population Health Institute, Fort Collins, CO, USA
C. McCONNEL
Affiliation:
Colorado State University, Department of Clinical Sciences, Animal Population Health Institute, Fort Collins, CO, USA
S. RAO
Affiliation:
Colorado State University, Department of Clinical Sciences, Animal Population Health Institute, Fort Collins, CO, USA
R. MAGNUSON
Affiliation:
Colorado State University, Department of Clinical Sciences, Animal Population Health Institute, Fort Collins, CO, USA
D. R. HYATT
Affiliation:
Colorado State University, Department of Clinical Sciences, Animal Population Health Institute, Fort Collins, CO, USA
L. LINKE
Affiliation:
Colorado State University, Department of Clinical Sciences, Animal Population Health Institute, Fort Collins, CO, USA
*
*Author for correspondence: Ms. C. Stenkamp-Strahm, Colorado State Veterinary Medicine and Biomedical Sciences, 1644 Campus Delivery, Fort Collins, CO 80523, USA. (Email: cstenkam@lamar.colostate.edu)
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Summary

Among pathogens shed by cattle, Escherichia coli O157 ranks highest in those causing human illness. To date, prevalence and risk factors for O157 shedding have been assessed in feedlot, but not dairy cattle. The study aimed to determine prevalence levels and risk factors for O157 atypical enteropathogenic E. coli (aEPEC) and enterohaemorrhagic E. coli (EHEC) shedding in dairy cattle. Dairy cattle (n = 899) within the first 21 days of lactation were sampled monthly over the course of 1 year, on three dry lot dairies surrounding Fort Collins, CO. During visits multiple factors were measured (disease history, pharmaceutical use, climate measures, etc.), and cattle faeces were collected and assessed for presence of O157 and virulence genes. Logistic regression analysis was performed using O157 outcomes and measured factors. Prevalence of O157 aEPEC was 3·7%, while EHEC was 3·0%. Many potential risk factors were highly correlated, and used to build separate multivariable models. An increase in humidity was positively associated with aEPEC, while fluid faeces and history of disease showed a negative association. Meanwhile, an increase in temperature and antibiotic treatment was positively associated with EHEC, while more days in milk, higher hygiene score and cow contact were negatively associated. These results may guide mitigation strategies that reduce O157 shedding, and contamination of the human food chain.

Keywords

AntibioticsEscherichia coli (E.coli)
Type
Original Papers
Information
Epidemiology & Infection , Volume 145 , Issue 1 , January 2017 , pp. 115 - 125
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Copyright
Copyright © Cambridge University Press 2016 

INTRODUCTION

Escherichia coli O157:H7 infection continues to be one of the most common food animal-borne human diseases. National Centers for Disease Control surveillance estimates that upwards of 96 000 human cases occur annually, causing symptoms of bloody diarrhoea, abdominal cramps, and haemolytic uraemic syndrome [1, Reference Nguyen and Sperandio2]. Historically, outbreaks have occurred after the pathogen is introduced to the human food chain through bovine products or contaminated produce, or through direct human contact with cows [Reference Croxen3]. Understanding and reducing the presence and dissemination of E. coli O157:H7 (O157) from bovine hosts remains paramount to ultimately mitigating human infection with this organism.

The pathogenicity of O157 strains shed by cattle is defined by the presence of virulence genes retained on mobile genetic elements [Reference Gyles4]. These genes include stx1 and stx2, which produce shiga toxins and exist on phage DNA [Reference Croxen3]. The virulence gene eae lies in a pathogenicity island and encodes the protein intimin, which allows bacterial adherence to epithelial cells and subsequent attaching-and-effacing lesions in humans and cattle [Reference Cornick, Booher and Moon5]. Because of the mobile nature of these elements, serotyping alone is an inferior method to use when determining the pathogenicity of E. coli strains [Reference Lambertini6]. Indeed, cattle have been shown to harbuor O157 pathotypes with severe human infectivity, containing both stx and eae genes (enterohaemorrhagic E. coli; EHEC), yet they may also harbour the O157 pathotype containing only eae, or eae with a bundle-forming pilus (bfp) gene (atypical enteropathogenic E. coli; aEPEC, and enterepathogenic E. coli) [Reference Bieber7]. O157 aEPEC is an E. coli variant from which EHEC likely descended, and although less studied may have a high prevalence on dairy farms and an ability to cause serious diarrhoeic infection and calf diarrhoeal disease [Reference Feng8, Reference Monaghan9]. Not all studies to date have characterized the nature of the O157 pathogen beyond serotype, yet this is a critical step in truly understanding bovine transmission dynamics and human health consequences [Reference Cernicchiaro10, Reference Williams, Ward and Dhungyel11].

Dairy cattle are unique in their ability to contaminate diverse food products including milk, meat, produce, and manure-fertilized crops. Even though O157 is ubiquitous in dairy herds across the United States, risk factors for colonization and shedding dynamics have more commonly been studied in beef herds [Reference Berry and Wells12, Reference Meyer-Broseta13]. Dairy studies are especially relevant due to the increasing popularity of drinking raw milk, and the fact that high prevalence levels of O157 have been noted in the few published studies [Reference Cobbaut14Reference Williams17]. Previous work has shown several environmental risk factors for dairy O157 shedding, including season, temperature, humidity, rainfall and solar exposure [Reference Williams17]. Herd-level variables of importance appear to be dairy production methods, the size of herd, use of total mixed ration or pasture growth, methods for manure storage and ventilation, and number of birds present [Reference Cernicchiaro10, Reference Ferreira15]. To our knowledge, O157 shedding studies that include dairy cow health and treatment data have yet to be performed, but one study that assessed lactation characteristics determined that the parity, number of days in milk, somatic cell count, and milk content of individuals were linked with shedding status [Reference Menrath18]. Given the factors that may influence shedding, early lactation cows exposed to nutritional, environmental and social changes, along with high levels of metabolic and hormonal stress due to calving and lactation, are thought to present a high-risk group [Reference Jacob, Callaway and Nagaraja19].

In the United States, the intermittent nature and daily variation of bovine colonization with O157 indicates that implementation of a longitudinal sampling scheme is necessary to fully appreciate and define shedding dynamics [Reference Williams, Ward and Dhungyel11, Reference Menrath18, Reference Robinson20]. Importantly, those animals shedding high quantities of the pathogen (‘high-shedders’; >103–104 c.f.u./g faeces) may account for the majority of O157 contamination within a herd, increasing animal-to-animal transmission and risk of food chain contamination [Reference Menrath18, Reference Cobbold21, Reference Omisakin22]. When classifying cows based on O157 shedding magnitude vs. positive shedding alone, outcomes for risk factor analyses can become altered [Reference Williams17].

Determining the risk factors for individual dairy cow O157 shedding may provide a framework within which to develop targeted prevention or treatment strategies to quell shedding and the subsequent introduction of pathogenic O157 to the human food chain. In an attempt to gain a comprehensive picture of dairy O157 shedding dynamics, the present study aimed to determine O157 shedding status, magnitude, and virulence in early lactation dairy cattle from three northern Colorado dairy herds sampled monthly over the course of 1 year. Concurrently, environmental, individual animal, and herd-level data were collected for inclusion in multivariable risk factor analyses.

METHODS

Samples and data collection

Three dry-lot dairies located within a 20-mile radius of Fort Collins, Colorado and representing a combined population of 2750 lactating cattle were utilized for the study. Herds were sampled monthly (every 2–4 weeks) for a period of 1 year (July 2013–June 2014, n = 939, representing 899 individuals). Although a few cows were sampled in duplicate, each sample was considered independent due to the daily variation in shedding, change of season between sample acquisition, and variation in lactation characteristics (days in milk, disease and treatment status, contact with other cows, etc.) between collections. Herd 3 could not be sampled during December due to barn construction. During sampling, 10 g faeces were collected from cows within the first 21 days of lactation via rectal palpation. As the herds studied calve on a year-round basis, cattle sampled tended to be evenly dispersed within this 21-day lactation window. At collection the rectal temperature, faecal consistency, hygiene and body condition scores for each animal were recorded, as well as pen stocking number (cow contact). Management of the herds studied included removal of calves from the dam immediately post-partum. As youngstock are reared in geographically separated individual hutches, it is of note that the variable ‘cow contact’ measures only the influence of other adult cows. The level of precipitation, ambient average temperature and humidity were determined each week sampling was completed using National Oceanic and Atmospheric Administration values (www.noaa.gov). Animal life history features including lactation number, calving ease, days in milk, prior disease, and disease treatments were obtained from on-farm computer record systems (Dairy Comp 305, Valley Agricultural Software, USA). Diseases and injuries catalogued in Dairy Comp and collected for analysis included history of bloat, diarrhoea, dystocia, haemorrhagic bowel syndrome (HBS), Johne's disease, ketosis, hoof lameness, lameness due to injury, mastitis, metritis, pneumonia, retained placenta, udder injury, metabolic symptoms, oedema, abomasal ulceration, displaced abomasum, and fever. All recorded treatments were analysed, and included ceftiofur, ampicillin, oxytetracycline, pirlimycin, cephapirin, flunixin meglumine, dexamethasone, and aspirin administration. Disease and treatment data were only collected for the given lactation cycle. Specific definitions for variable measures can be found in Supplementary Appendix 1.

Given the data collected, treatment types were further collapsed and assessed as broad categories by type (antibiotic treatment, other drug treatment, never treated) and administration and type (intramammary antibiotic, systemic antibiotic, systemic anti-inflammatory, never treated). Categories were also created for cows receiving multiple treatment types (Supplementary Appendix 1). The covariate ‘disease’ was also assessed using a binary (disease/no disease) method. Since many cows were listed as having a disease but not being treated, a binary variable of ‘disease or treatment’ vs. ‘no disease or treatment’ was created. While over-assessment of recorded risk factors may result in an ultimate loss of model information, all classifications herein were evaluated in an attempt to better understand if disease or treatment may have influenced shedding status, as this is a novelty of the present study. Other variables were collapsed based on biological plausibility and historical relevance. For example, parity comparisons in the dairy setting are often reduced to compare first to second, or ⩾third lactation cycles, as cattle commonly remain in the system only to lactation cycles 2–5. Faecal consistency was broken down to compare a level of 3 (normal consistency) to levels 1 + 2 (more liquid) and levels 4 + 5 (more solid). All data collected for use as variables in regression modelling are described in Table 1, and collapsed variables are further described within Tables 2–6.

Table 1. Variables used in regression analysis

GEE, Generalized estimating equations; SRP, Salmonella siderophore receptor and porin; HBS, haemorrhagic bowel syndrome; n.a., not applicable.

Isolation and characterization of O157 pathotypes

O157 isolation was performed following selective enrichment and detection ‘gold standard’ procedures. O157 presence and enumeration was assessed initially through direct plating. Samples were mixed 1:10 in buffered peptone water (BPW) for both enrichment and direct plating. One hundred μl was spread-plated on sorbitol MacConkey agar with BCIG (Oxoid Diagnostic Reagents, UK) containing 1·25 mg potassium tellurite and 0·025 mg cefixime (CT-SMAC-BCIG; HiMedia Laboratories, India). Plates were incubated at 37 °C for 24 h [Reference March and Ratnam23]. As pathogenic O157 has been known to adapt a sorbitol-fermenting phenotype within 24 h, ‘suspect’ O157 colonies seen on plates throughout experiments were deemed as those with straw, grey, pink-grey, or too small/difficult to characterize colony coloration [Reference Ayaz, Gencay and Erol24, Reference Schmidt25].

After direct plate incubation, plates containing ⩾100 suspect colonies were chosen for latex agglutination. Three to 15 colonies per plate, depending on how many colonies were determined ‘suspect’, were tested for O157 by agglutination using an E. coli O157 latex kit, following the manufacturer's instructions (Oxoid Diagnostic Reagents, UK). Positive colonies were enriched in BPW for 6 h and stored at −80 °C in 10% sterile glycerol. For PCR experiments, 10 μl of thawed isolates were centrifuged at 5000 g for 5 min and re-suspended in 30 μl molecular grade water. Once re-suspended, 5 μl culture template was placed into Qiagen Multiplex PCR Plus kit reaction master mixes, according to the manufacturer's instructions (Qiagen, The Netherlands). Briefly, each 25 μl PCR reaction consisted of 12·5 μl master mix, 2·5 μl primer mix containing 0·2 μ m of each primer, 5 μl molecular grade water, and 5 μl culture template. The thermal cycling conditions consisted of an initial incubation at 95 °C for 5 min to activate the polymerase, followed by 40 cycles of amplification with denaturation at 95 °C for 30 s, annealing at 57 °C for 1 min and 30 s, and extension at 72 °C for 30 s, ending with a final extension at 68 °C for 10 min. Thermocycling was performed using a Bio-Rad S1000 Thermal Cycler (Bio-Rad, Australia). PCR products were analysed by agarose gel electrophoresis using a 2% agarose gel (Lonza Group Ltd, Switzerland).

The faecal dilution remaining after direct plating was enriched for 6 h at 37 °C, and stored overnight at 4 °C. Enriched samples not confirmed as O157 positive through direct plating (those not ‘high-shedding’; having either none or <103–104 c.f.u./g faeces) were subjected to immunomagnetic separation (IMS) using Dynabeads anti-E. coli O157 and a BeadRetriever System (Life Technologies, Norway). IMS samples were subsequently plated onto CT-SMAC-BCIG and incubated for 24 h at 37 °C. Suspect colonies were confirmed by latex agglutination and PCR targeting the O157 rfb gene [Reference Wang, Clark and Rodgers26]. All rfb (and thus O157) positive isolates were subsequently PCR tested for stx1, stx2, and eaeA (a variant of the eae intimin gene) using the same PCR protocol outlined above [Reference Paton and Paton27].

In addition to isolates that contained rfb, eaeA, and any stx genes (EHEC), or rfb and eaeA genes alone (aEPEC), many were seen to only harbour the O157 rfb gene. To further characterize these allegedly non-virulent isolates, complete typing (O, H, toxin and fimbriae) was performed on a subset of samples. Briefly, an ‘rfb only’ isolate was selected from each herd, at three staggered time points throughout the year-long sample period (nine isolates in total). Typing was performed by the American Association of Veterinary Laboratory Diagnosticians (AAVLD)-accredited E. coli reference centre at Pennsylvania State University, in the College of Agricultural Sciences.

Statistical analyses

Monthly and annual prevalence of pathogenic variants of O157 were estimated within and between herds. Confidence intervals of shedding prevalence were calculated using the Wilson procedure with a correction for continuity. Shedding outcomes with respect to presence of ‘O157 pathotype’ were evaluated for association with potential risk factors. Pathotypes were assessed in separate models because of their different indications for human disease and food safety, and were either those bacteria with the presence of both rfb and eaeA genes (low pathogenicity aEPEC), or those with presence of rfb, eaeA, and any stx genes (high pathogenicity EHEC). Potential risk factors associated with pathotype outcome were pre-selected using a threshold of P < 0·25 in a univariate logistic regression analysis. As a main project goal was to identify the specific factors most significantly associated with the risk of shedding, factors that showed significant correlations or associations with one another were then included in separate multivariable models. This strategy was also chosen because the adoption of future cattle management methods, aimed at reducing O157 in the food chain, may ultimately be more conceivable through targeting one significant collinear factor and not the other. For each model, a backward stepwise selection process was implemented using a P-to-retain criteria of 0·1 at each step. Final covariate selection was done using a P value of < 0·05. Interaction terms between all significant variables were evaluated for significance at P < 0·05. All multivariable analyses were adjusted for the effect of ‘dairy herd’ using a generalized estimating equation (GEE) approach. Models created for the same outcome were assessed for biological plausibility and compared using QIC (quasi-likelihood independent model criterion) values based on GEE, to determine models with the best working correlation structure for the data and to identify the most robust shedding predictors based on model fit [Reference Cui28]. All statistical analyses were performed using SAS v. 9.4 (SAS Institute Inc., USA).

RESULTS

Only one sample was confirmed as O157 positive after direct plating, and deemed to originate from a ‘high-shedder’ (>10–3–104 c.f.u./g faeces when collected). The sample was collected mid-September from herd 2, and contained all tested virulence genes.

Univariate and multivariable statistical analysis was not performed using stratified shedding outcomes of ‘high’ or ‘low’ given the lack of high-shedder detection. Samples were simply classified as positive (⩾102 c.f.u./g faeces) or negative for O157 pathotypes after IMS, latex agglutination, and PCR. Level of detection is based on IMS manufacturer indication, which claims the ability to detect as low as 100 c.f.u./g faeces in enriched samples with high amounts of background flora.

Prevalence of E. coli O157

During the year-long study period, 939 faecal samples from early lactation cows were collected during 38 separate visits. One hundred and eighty-nine [21%, 95% confidence interval (CI) 17·6–22·9] isolates contained the rfb gene alone, 35 (3·9%, 95% CI 2·7–5·2) contained both rfb and eaeA (aEPEC), 28 (3·1%, 95% CI 2·0–4·3) contained rfb, eaeA, and any or both stx genes (EHEC), and five (0·55%, 95% CI 0·19–1·3%) contained rfb and any stx genes. For EHEC isolates, a total of 22 contained the stx2 gene (79%, 95% CI 59·0–91·0), 26 contained stx1 (93%, 95% CI 75·1–98·8), and 20 contained both stx1 and stx2 (71%, 95% CI 51·1–86·1).

The number of aEPEC and EHEC isolates varied by dairy herd and season, with a majority of O157 pathotypes being isolated between June and October (Fig. 1). Herd 1 had the greatest proportion of aEPEC isolates (20/35) and a low proportion of EHEC (5/28). Herd 2 had the greatest proportion of EHEC isolates (23/28) and a moderate number of aEPEC (8/35). In comparison, herd 3 showed relatively few isolates of aEPEC (7/35) and no EHEC isolates (Fig. 1).

Fig. 1. Monthly prevalence of atypical enteropathogenic E. coli (aEPEC) and enterohaemorrhagic E. coli (EHEC) measured for (a) herd 1, (b) herd 2 and (c) herd 3, respectively. No isolates collected from herd 3 were positive for EHEC.

A subset of isolates possessing only the rfb gene were typed by the Pennsylvania State E. coli reference centre, where all were confirmed to contain the rfb gene and lack the stx1, stx2, eae, STa, cnf1, cnf2, CS31A, F41, and K99 virulence genes. Isolates were all sorbitol fermenting and H+, being either O157:H12, O157:H45 or O157:H+ (untypable).

Significant factors

Risk-factor categories were collapsed based on the power of study data and biological plausibility for comparing measured levels (Table 1). For aEPEC shedding, several variables univariately influenced status (Table 2). Many pre-selected aEPEC parameters were significantly (P < 0·05) associated with one another (Table 3). Each set of variables without correlations was included in a multivariable model with ‘dairy herd’ as a clustering constraint. Backward stepwise regression was used to determine multiple significant models for aEPEC (Supplementary Appendix 2).

Table 2. Herd, climate and individual cow parameters pre-selected (P < 0·25) for inclusion in aEPEC modelling

aEPEC, Atypical enteropathogenic E. coli; OR, Odds ratio; CI, confidence interval; n.a., not applicable.

* Comparison odds of shedding aEPEC.

Reference category.

Table 3. Pre-selected parameters for aEPEC modelling found to be correlated at P < 0·05

aEPEC, Atypical enteropathogenic E. coli.

Many factors were also univariately pre-selected (P ⩽ 0·25) for association with EHEC shedding (Table 4). Significant associations (P < 0·05) between univariately significant EHEC parameters can be found in Table 5. All EHEC multivariable models determined using combinations of non-collinear factors can be found in Supplementary Appendix 3.

Table 4. Herd, climate and individual cow parameters pre-selected (P < 0·25) for inclusion in EHEC modelling

EHEC, Enterohaemorrhagic E. coli; OR, Odds ratio; CI, confidence interval; n.a., not applicable.

* Comparison odds of shedding EHEC.

Reference category.

Table 5. Pre-selected parameters for EHEC modelling found to be correlated at P < 0·05

EHEC, Enterohaemorrhagic E. coli.

Biological significance and QIC correlation structure values were used to determine two final ‘best’ multivariate models for aEPEC and EHEC (Table 6). In a final model, history of any disease or treatment, as a single factor, significantly reduced the odds of shedding aEPEC. In a second model, an increase in the average weekly humidity significantly increased, and a more watery faecal score significantly decreased, the odds of shedding aEPEC. For EHEC, an increase in hygiene score and cow contact were shown to reduce the odds of shedding, while recent treatment with any antibiotic significantly increased the odds. In a second model, an increase in the average weekly temperature increased the odds of EHEC shedding, while an increase in the number of days in milk reduced the odds of shedding.

Table 6. Final multivariable models determined for aEPEC and EHEC shedding, using ‘dairy herd’ as a clustering constraint

aEPEC, Atypical enteropathogenic E. coli; EHEC, Enterohaemorrhagic E. coli; OR, Odds ratio; CI, confidence interval; QIC, quasi-likelihood independent model criterion.

* Comparison odds of shedding.

Reference category.

DISCUSSION

E. coli O157 has been shown to adapt a sorbitol-fermenting phenotype within 24 h, and sorbitol-fermenting strains have historically caused human disease outbreaks and harboured a high number of virulence genes [Reference King29]. Many O157 strains were isolated in the current study in an attempt to detect all bacteria, sorbitol fermenting and non-sorbitol fermenting, of public health importance. Some studies to date have not PCR-confirmed IMS-isolated O157 strains, resulting in unknown O157 pathogenicity. The multitude of non-virulent O157 isolates found in the current study further validates that PCR confirmation of virulence genes during O157 studies is an absolute necessity.

Strains not confirmed as having eaeA or stx genes in the current study were confirmed to have O157 and H12 or H45 flagellar antigens. H12 subtypes have previously been isolated from watersheds and cattle at slaughter, and non-pathogenic strains have been used as control strains in EHEC studies [Reference Alonso30, Reference Ingram31]. Although H12 strains can become infected with similar phages to O157:H7, it is unknown whether strains isolated in the current study retain an ability to become pathogenic. When isolated, O157:H45 strains commonly have contained EPEC virulence genes (bfp, eae, tir) [Reference Hazen32, Reference Mora33]. These strains have been detected in human prevalence and gastroenteritis outbreak studies [Reference Park34, Reference Cookson35]. Strains in the current study appeared avirulent based on AAVLD typing, and future studies are needed to determine if they have capacity to acquire mobile virulence elements.

Of the dairies studied, shedding prevalence of aEPEC and EHEC were both relatively low (3·7% and 3%, respectively). Although studies to date have not assessed aEPEC prevalence, other studies of stx and O157:H7 dairy prevalence have shown both higher (72·7%, 11·1–32·3%) [Reference Ferreira15, Reference Menrath18] and lower (1%) levels [Reference Cernicchiaro10]. Importantly, high-shedding cattle have been hypothesized to influence herd EHEC propagation, and only one was observed in the current study [Reference Cobbold21, Reference Omisakin22]. To date, this is the first assessment of EHEC prevalence on dairies in the Rocky Mountain biome, so it is possible that lower shedding prevalence and measured outcomes may be inherent to the particular environment studied.

aEPEC was isolated more commonly than EHEC on the farms studied. To our knowledge this shedding outcome has not been modelled previously, but may pose a public health risk. Although not associated with haemolytic uremic syndrome like EHEC, the intimin gene conserved between aEPEC and EHEC strains imparts the ability for aEPEC to cause attaching-and-effacing lesions, watery diarrhoea, and paediatric infection [Reference Cookson35]. A high infective dose is required for human EPEC infection [Reference Bieber7], which is probably due to its lower virulence as a human pathogen. However, strong evidence exists for EHEC strain evolution from EPEC, and a close homology among these strains [Reference Croxen3]. This homology and the mobile nature of phage-transmitted stx genes indicates that modelling aEPEC may be advantageous for both the prediction of future foodborne EPEC infections, and potentially understanding the emergence of new stx strains.

Final multivariable models for aEPEC revealed positive associations between shedding and increased humidity, while watery faeces and a recent history of any disease or treatment showed reduced odds of shedding. In prior studies climatic factors and faecal consistencies have been shown to influence virulent O157 shedding in dairy cattle [Reference Williams17]. The negative association of disease and treatment with aEPEC shedding is difficult to interpret. The stress that accompanies disease processes and administration of treatments may influence intrinsic immune or physiological bovine processes that permit less ideal colonization conditions of the lower gastrointestinal tract to ingested aEPEC strains. However, future studies are required to confirm this assumption.

Multivariable models of EHEC revealed a negative association between shedding and a high hygiene score, greater cow contact, and a higher number of days in milk. An increased hygiene score and greater cow contact appear counterintuitive with historical factors thought to influence shedding. Although a subjective measure, hygiene scores are meant to reflect animal cleanliness, and cleanliness of the farm environment. Dirtier cows may reflect a combination of changes in environmental parameters (rainfall, humidity) more discretely than those parameters do when measured directly and individually. The exact mechanism by which this influences shedding remains to be determined. Cows housed with a greater number of other cows would presumably have an increased risk of shedding pathogenic O157, both through an increase in exposure and stress. The current study revealed an opposite trend, and this may be due to the daily employee modifications of pen size depending on cow number, which was especially evident based on the management of herd 2 (having the highest prevalence of EHEC). A more meaningful measure of animal contact would have taken into account both the number of cows in a pen and the size of the enclosure, which was not possible due to daily fluctuations. With changes in pen size it is possible that increasing animal numbers actually reflected a less confined environment for the animals studied. Previous studies have shown that cow age, a higher parity, and greater number of days in milk may be associated with reduced EHEC shedding [Reference Cobbaut14, Reference Menrath18]. The current study showed that both a higher parity and number of days in milk were associated with reduced shedding, with a significant interaction of these factors (Supplementary Appendix 3 and Table 6). Cattle were studied within the first 21 days of milk, so it is of note that the findings associated with this initial time from calving may become more or less apparent, should studies of shedding be carried further into the lactation period. Regardless, these results continue to support a notion that early lactation heifers, experiencing their initial calving and metabolic challenge of milk production, are a group more likely to shed EHEC. These individuals may therefore be targeted during future EHEC intervention studies.

Recent treatment with an antibiotic and a higher environmental temperature were significantly associated with EHEC shedding. Temperature has been previously implicated in O157 shedding in both beef and dairy settings, especially as it pertains to season [Reference Williams17, Reference Menrath18]. To date, this is the first study that has assessed medical treatments given during the current lactation, and their influence on the risk of a cow to shed EHEC. Results showed that cows treated with any antibiotic (both systemic and intramammary administration) had an increased risk of shedding compared to those individuals receiving no treatments. This indicates that antibiotic administration may modulate the bovine flora in a manner that facilitates future colonization with EHEC. Although prevalence levels had low power to detect bovine disease parameters that influenced EHEC, the collapsed variable that investigated cows with any disease or treatment history indicated that these animals are at increased risk of shedding, compared to non-diseased and non-treated cows, respectively (Supplementary Appendix 3). Taken together, these EHEC results support an idea that early lactation heifers with a reported status of disease, and history of receiving any antibiotic during the current lactation, may be the individuals most likely to contribute to EHEC shedding and contamination of the farm.

The differences in aEPEC and EHEC shedding prevalence between farms are likely due to variation in management factors, specifically those related to nutrition and modulation of the gastrointestinal tract. These factors may include feeding ionophores, and using haemorrhagic bowel syndrome (HBS) and Salmonella siderophore receptor and porin (SRP) vaccines. Herds 1 and 3 were both fed ionophores during the study period. Herd 1 also employed use of a Salmonella Newport SRP vaccine (Epitopix, Willmar, USA) while herd 2 utilized an autogenous Clostridium perfringens type A, HBS vaccine. Parallels between management variability and O157 pathotype prevalence indicates a need to look at gastrointestinal bacterial communities under the influence of these managerial factors, and determine the specific intestinal environment that facilitates or impedes O157 growth. To truly understand the ecology of O157 shedding and farm prevalence, future studies should include an assessment of calves and cattle beyond the early lactation period, and a comparison of cows in ill-health with treatment history (specifically antibiotic use for EHEC) to those with no prior disease or history of treatment administration.

Given its ubiquity in a multitude of unprocessed food products and ability to cause outbreaks and isolated incidents of human illness worldwide, E. coli O157 remains a pertinent public health concern. Many strains and pathotypes of the O157 pathogen exist, having been isolated and characterized during instances of disease. Both the current and previous studies have shown that shedding of this pathogen from bovine hosts is complex, and may vary due to season, environment, specific host factors, and bacterial pathotype. The current study aimed to comprehensively model the shedding of O157 pathotypic variants from reservoir dairy hosts. Our findings related to risk factors and shedding dynamics of pathogenic strains can guide future studies aimed to detect dairy hosts colonized with O157, and influence the development and assessment of prevention or treatment techniques directed at reducing O157 shedding and food chain contamination.

SUPPLEMENTARY MATERIAL

For supplementary material accompanying this paper visit http://dx.doi.org/10.1017/S0950268816001928.

ACKNOWLEDGEMENTS

The authors acknowledge Dave Hicks and Michael Russell in the CSU Veterinary Diagnostic Laboratory for their expertise in identifying and screening E. coli O157 isolates of varying pathotype. The authors also thank several students who aided in faecal culture and isolation of samples: Paige Tenneson, Meagan Chriswell, Clarissa Freemyer, and Sean Montgomery. The authors are sincerely indebted to the owners and personnel of the three dairies for their invaluable collaboration during the study.

This research was funded, in part, by the High Plains Intermountain Center for Agricultural Health and Safety, the Colorado State University Infectious Disease Supercluster, and USDA Animal Health and Disease Formula Funds.

DECLARATION OF INTEREST

None.

References

REFERENCES

1. Centers for Disease Control and Prevention. National Shiga toxin-producing Escherichia coli (STEC) surveillance overview. Atlanta, Georgia: CDC, 2012, p. 4.Google Scholar
2. Nguyen, Y, Sperandio, V. Enterohemorrhagic E. coli (EHEC) pathogenesis. Frontiers in Cellular and Infection Microbiology 2012; 2.CrossRefGoogle ScholarPubMed
3. Croxen, MA, et al. Recent advances in understanding enteric pathogenic Escherichia coli . Clinical Microbiology Review 2013; 26: 822880.CrossRefGoogle ScholarPubMed
4. Gyles, CL. Shiga toxin-producing Escherichia coli: an overview. Journal of Animal Science 2007; 85: E45–62.CrossRefGoogle ScholarPubMed
5. Cornick, NA, Booher, SL, Moon, HW. Intimin facilitates colonization by Escherichia coli O157:H7 in adult ruminants. Infection and Immunity 2002; 70: 27042707.CrossRefGoogle ScholarPubMed
6. Lambertini, E, et al. Dynamics of Escherichia coli virulence factors in dairy herds and farm environments from a longitudinal study in the United States. Applied Environmental Microbiology 2015; 81: 44774488.CrossRefGoogle ScholarPubMed
7. Bieber, D, et al. Type IV pili, transient bacterial aggregates, and virulence of enteropathogenic Escherichia coli . Science 1998; 280: 21142118.CrossRefGoogle ScholarPubMed
8. Feng, PC, et al. Clonal relations of atypical enteropathogenic Escherichia coli O157:H16 strains isolated from various sources from several countries. FEMS Microbiology Letters 2012; 337: 126131.CrossRefGoogle Scholar
9. Monaghan, A, et al. Serotypes and virulence profiles of atypical enteropathogenic Escherichia coli (EPEC) isolated from bovine farms and abattoirs. Journal of Applied Microbiology 2013; 114: 595603.CrossRefGoogle ScholarPubMed
10. Cernicchiaro, N, et al. Association of wild bird density and farm management factors with the prevalence of E. coli O157 in dairy herds in Ohio (2007–2009). Zoonoses and Public Health 2012; 59: 320329.CrossRefGoogle ScholarPubMed
11. Williams, KJ, Ward, MP, Dhungyel, OP. Daily variations in Escherichia coli O157 shedding patterns in a cohort of dairy heifers at pasture. Epidemiology and Infection 2015; 143: 13881397.CrossRefGoogle Scholar
12. Berry, ED, Wells, JE. Escherichia coli O157:H7: recent advances in research on occurrence, transmission, and control in cattle and the production environment. Advances in Food Nutrition Research 2010; 60: 67117.CrossRefGoogle Scholar
13. Meyer-Broseta, S, et al. Review of epidemiological surveys on the prevalence of contamination of healthy cattle with Escherichia coli serogroup O157:H7. International Journal of Hygiene and Environmental Health 2001; 203: 347361.CrossRefGoogle ScholarPubMed
14. Cobbaut, K, et al. Escherichia coli O157 prevalence in different cattle farm types and identification of potential risk factors. Journal of Food Protection 2009; 72: 18481853.CrossRefGoogle ScholarPubMed
15. Ferreira, MR, et al. Isolation, prevalence, and risk factors for infection by shiga toxin-producing Escherichia coli (STEC) in dairy cattle. Tropical Animal Health and Production 2014; 46: 635639.CrossRefGoogle ScholarPubMed
16. Jackson, EE, et al. Detection and enumeration of four foodborne pathogens in raw commingled silo milk in the United States. Journal of Food Protection 2012; 75: 13821393.CrossRefGoogle ScholarPubMed
17. Williams, KJ, et al. Risk factors for Escherichia coli O157 shedding and super-shedding by dairy heifers at pasture. Epidemiology and Infection 2015; 143: 10041015.CrossRefGoogle ScholarPubMed
18. Menrath, A, et al. Shiga toxin producing Escherichia coli: identification of non-O157:H7-Super-Shedding cows and related risk factors. In: Gut Pathogens England 2010: 7.CrossRefGoogle ScholarPubMed
19. Jacob, ME, Callaway, TR, Nagaraja, TG. Dietary interactions and interventions affecting Escherichia coli O157 colonization and shedding in cattle. Foodborne Pathogens and Disease 2009; 6: 785792.CrossRefGoogle ScholarPubMed
20. Robinson, SE, et al. Intermittent and persistent shedding of Escherichia coli O157 in cohorts of naturally infected calves. Journal of Applied Microbiology 2004; 97: 10451053.CrossRefGoogle ScholarPubMed
21. Cobbold, RN, et al. Rectoanal junction colonization of feedlot cattle by Escherichia coli O157:H7 and its association with supershedders and excretion dynamics. Applied Environmental Microbiology 2007; 73: 15631568.CrossRefGoogle ScholarPubMed
22. Omisakin, F, et al. Concentration and prevalence of Escherichia coli O157 in cattle feces at slaughter. Applied Environmental Microbiology 2003; 69: 24442447.CrossRefGoogle ScholarPubMed
23. March, SB, Ratnam, S. Sorbitol-MacConkey medium for detection of Escherichia coli O157:H7 associated with hemorrhagic colitis. Journal of Clinical Microbiology 1986; 23: 869872.CrossRefGoogle ScholarPubMed
24. Ayaz, ND, Gencay, YE, Erol, I. Prevalence and molecular characterization of sorbitol fermenting and non-fermenting Escherichia coli O157:H7(+)/H7(-) isolated from cattle at slaughterhouse and slaughterhouse wastewater. International Journal of Food Microbiology 2014; 174: 3138.CrossRefGoogle ScholarPubMed
25. Schmidt, H, et al. Escherichia coli O157:H7 and O157:H(-) strains that do not produce Shiga toxin: phenotypic and genetic characterization of isolates associated with diarrhea and hemolytic-uremic syndrome. Journal of Clinical Microbiology 1999; 37: 34913496.CrossRefGoogle Scholar
26. Wang, G, Clark, CG, Rodgers, FG. Detection in Escherichia coli of the genes encoding the major virulence factors, the genes defining the O157:H7 serotype, and components of the type 2 Shiga toxin family by multiplex PCR. Journal Clinical Microbiology 2002; 40: 36133619.CrossRefGoogle ScholarPubMed
27. Paton, AW, Paton, JC. Detection and characterization of Shiga toxigenic Escherichia coli by using multiplex PCR assays for stx1, stx2, eaeA, enterohemorrhagic E. coli hlyA, rfbO111, and rfbO157. Journal Clinical Microbiology 1998; 36: 598602.CrossRefGoogle ScholarPubMed
28. Cui, J. QIC program and model selection in GEE analyses. Stata Journal 2007; 7: 209220.CrossRefGoogle Scholar
29. King, LA, et al. Foodborne transmission of sorbitol-fermenting Escherichia coli O157:[H7] via ground beef: an outbreak in northern France, 2011. Clinical Microbiology and Infection 2014; 20: O113601144.CrossRefGoogle ScholarPubMed
30. Alonso, S, et al. Fecal carriage of Escherichia coli O157:H7 and carcass contamination in cattle at slaughter in northern Italy. International Microbiology 2007; 10: 109116.Google ScholarPubMed
31. Ingram, DT, et al. Use of zero-valent iron biosand filters to reduce Escherichia coli O157:H12 in irrigation water applied to spinach plants in a field setting. Journal of Applied Microbiology 2012; 112: 551560.CrossRefGoogle Scholar
32. Hazen, TH, et al. Draft genome sequences of three O157 enteropathogenic Escherichia coli isolates. Genome Announcements 2013; 1.CrossRefGoogle ScholarPubMed
33. Mora, A, et al. HeLa-cell adherence patterns and actin aggregation of enteropathogenic Escherichia coli (EPEC) and Shiga-toxin-producing E. coli (STEC) strains carrying different eae and tir alleles. International Microbiology 2009; 12: 243251.Google ScholarPubMed
34. Park, JH, et al. Diarrheal outbreak caused by atypical enteropathogenic Escherichia coli O157:H45 in South Korea. Foodborne Pathogens and Disease 2014; 11: 775781.CrossRefGoogle ScholarPubMed
35. Cookson, AL, et al. Relationship between virulence gene profiles of atypical enteropathogenic Escherichia coli and Shiga toxin-producing E. coli isolates from cattle and sheep in New Zealand. Applied Environmental Microbiology 2010; 76: 37443747.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Variables used in regression analysis

Figure 1

Fig. 1. Monthly prevalence of atypical enteropathogenic E. coli (aEPEC) and enterohaemorrhagic E. coli (EHEC) measured for (a) herd 1, (b) herd 2 and (c) herd 3, respectively. No isolates collected from herd 3 were positive for EHEC.

Figure 2

Table 2. Herd, climate and individual cow parameters pre-selected (P < 0·25) for inclusion in aEPEC modelling

Figure 3

Table 3. Pre-selected parameters for aEPEC modelling found to be correlated at P < 0·05

Figure 4

Table 4. Herd, climate and individual cow parameters pre-selected (P < 0·25) for inclusion in EHEC modelling

Figure 5

Table 5. Pre-selected parameters for EHEC modelling found to be correlated at P < 0·05

Figure 6

Table 6. Final multivariable models determined for aEPEC and EHEC shedding, using ‘dairy herd’ as a clustering constraint

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