ASSESSMENT OF ESCHERICHIA COLI AS AN INDICATOR OF MICROBIAL QUALITY OF IRRIGATION WATERS USE FOR PRODUCE

• Sponsoring Institution: National Institute of Food and Agriculture
• Project Status: COMPLETE
• Funding Source: HATCH
• Reporting Frequency: Annual
• Accession No.: 1001114
• Project Start Date: Oct 1, 2013
• Project End Date: Sep 30, 2018
• Program Code: [(N/A)]- (N/A)

Recipient Organization
UNIVERSITY OF ARIZONA
888 N EUCLID AVE
TUCSON,AZ 85719-4824

Performing Department
Soil, Water & Environmental Science

Non Technical Summary
The goals of this project are to evaluate currently available detection methods for the accurate assessment of Escherichia coli contamination in irrigation waters and provide guidance for interpretation of results through a revised risk based E.coli standard. Currently, there is concern that the false positive rate of E.coli detection may be high in these waters giving false indications of the level of risk from enteric pathogens. This may result in unnecessary costly interventions as well as inaccurate perception of risk among consumers. We propose evaluating three different commercial systems for E.coli detection in irrigation waters and assessing false positive rates by use of molecular technologies. As a secondary objective to evaluating E.coli as a reliable indicator, we propose using a Quantitative Microbial Risk Assessment (QMRA) to assess the use of E.coli as an accurate indicator of food safety risk using data collected in the first stage of this project coupled with existing information found in the scientific literature. Ultimately this work will offer recommendations towards the most reliable methods to be used by the produce industry to assess irrigation water contamination as well as a scientific risk-based E.coli guideline that growers can use to protect public health.

Animal Health Component

100%

Research Effort Categories

Basic

(N/A)

Applied

100%

Developmental

(N/A)

Classification

Knowledge Area (KA)	Subject of Investigation (SOI)	Field of Science (FOS)	Percent
712	0210	1100	100%

Knowledge Area
712 - Protect Food from Contamination by Pathogenic Microorganisms, Parasites, and Naturally Occurring Toxins;

Subject Of Investigation
0210 - Water resources;

Field Of Science
1100 - Bacteriology;

Keywords

e.coli

irrigation water

food safety

leafy greens

microbiology

water quality

Goals / Objectives
Phase 1: Determine the best method (most reliable, ease of use, low false positive rate) for E.coli detection in irrigation waters based on the comparison of three methods currently available for the detection of E.coli in irrigation waters. Determine influence of temperature and salinity (and other environmental factors) on false positive rates of these three methods for accurate E.coli detection in irrigation waters. Phase 2: Develop an exposure scenario (model) for E .coli in irrigation waters taking into consideration the type of irrigation method, the irrigated crop, the transfer rate of E.coli to the crop, and the E.coli survival post irrigation. Estimate the risk of illness from ingestion of various levels of E.coli from the proposed irrigation scenarios. Develop a simple, user friendly guideline (program or graph) for estimating risk of infection from the different irrigation scenarios (e.g., different levels of E.coli deposited, different crops irrigated). These guidelines will be compared to risks associated with the current guideline of 126 CFU/100 mL.

Project Methods
Field Sampling: Samples will be collected in three different agricultural areas: the University of Arizona research farms (Maricopa Agricultural Center-MAC and Yuma Agricultural Center-YAC) in Maricopa and Yuma, AZ, respectively, and the Imperial Valley (CA). These three locations represent a significant portion of winter leafy green production in the United States. Sample collection will take place during the winter growing season and additional select times of year to assess the effects of temperature, salinity and other environmental factors (e. g. sunlight intensity, precipitation). MAC samples will be collected by Dr. Rock, while Dr. Bright will collect the YAC and Imperial Valley samples during a minimum of eight sampling trips to these areas. Sampling will be focused in the winter growing season in order to assess conditions most frequently encountered produce growers. A total of 150 samples will be collected at each of the 3 locations for a total of 450 samples. On each sampling date, grab samples of water will also be collected from the irrigation system during scheduled irrigation events by reducing the water velocity manually at the irrigation control box and directing the irrigation spray into sterile bottles. Following collection, water samples will be placed on ice for transport to the laboratory. Sampling sites will be determined based on relative distance up-stream from the irrigation practice and each production field. This will be done in collaboration with University of Arizona faculty at YAC and MAC and cooperating grower partners. Laboratory Analysis: In the laboratory, water samples will be divided equally for testing by the three above methods for enumeration of E.coli. Methods 1 and 3 (MI agar and m-Coli Blue) involve sample processing using the membrane filter technique, which is widely accepted and approved as a procedure for monitoring water microbial quality in many countries (Rompré et al., 2002; USEPA, 2002a). Water samples will be filtered in three dilutions (100, 10, and 1.0 mL) through Whatman gridded filters (0.45 µm pore size, 152 mm diameter) (Whatman International Ltd., Kent, UK). For method 1 filters will be placed onto 60 mm Petri plates with prepared MI Agar with cefsulodin added at 5 mg L-1 153 to inhibit growth of Gram positive organisms and selected non-coliform Gram-negatives (e.g., Pseudomonas spp.). Plates are incubated at 37º C for 24-36 h before counting dark blue colonies presumptive for E.coli. Water samples aliquots for method (2), will be processed according to manufacturer instructions and quanti-trays will be read after 18 hours incubation at 37º C. Only wells fluorescing "blue" color will be selected for false positive confirmation.For method (3), the filters will be placed in a Petri plate containing an absorbent pad soaked in m-ColiBlue broth. Petri plate samples will be inverted and incubated at 35º C for 24 hrs. Following incubation colonies showing a blue color will be selected as presumptive for E.coli. m-ColiBlue24 broth has been approved by the EPA for monitoring drinking water and can also be used to detect coliforms and E.coli in other types of water (e.g., bottled, surface, ground, well) (US EPA, 40 CFR Parts 141, 143). Identification of False Positive Organisms: Microorganisms that test presumptively positive for E.coli on each of the three methods mentioned above but do not produce the 106-bp DNA fragment using PCR will be selected for sequencing for identification. Following regrowth in trypticase soy broth, the bacterial pellet will be used as a template for PCR 197 utilizing universal bacterial 63f [5'-CAG GCC TAA CAC ATG CAA GTC-3'] and 1387r [5'-198 ACG GGC GGT GTG TAC AAG-3'] primers (Marchesi et al., 1998). The resulting 1325-bp amplicons will be sequenced in both directions using an automated ABI Prism 377 DNA Sequencer (Applied Biosystems, Carlsbad, CA). Retrieved sequences will be aligned with completed bacterial genomes entered into the NCBI-BLAST database (NCBI-BLAST, 2010) to identify the organisms most closely aligned to the amplicons from false positive isolates. A minimum of 97% agreement with genomic sequences deposited in the database will be required to confirm the identity of each isolate. Development of risk scenarios: The probability of illness from exposure to different concentrations of E.coli in recreational waters is known (Cabelli, 1989). The observed illness may be caused by a variety of pathogens including bacteria, viruses and protozoa. However, the relationship between E.coli and pathogens causing human illness can be used to estimate probability of illness from different levels of exposure to E.coli. A certain amount of uncertainty exists in this approach because the concentrations and types of pathogens in irrigation waters may be different than those in bathing waters. However, many of the irrigation waters in the Western United States originate from reservoirs and/or rivers where recreation is common. The QMRA will be dependent on knowledge of the level of E .coli ingested on the produce by the consumer, determined from research reports showing transfer rates of E.coli from irrigation to the produce and its survival on the produce. This is dependent on both the type of irrigation method and type of produce. This information is available from the literature (Petterson et al., 2001) and our own studies (Stine et. al. 2005a; 2005b; Stine et al. submitted for publication). We have used a similar approach to estimate risks from produce by Salmonella and hepatitis A virus (Stine 2005a). This "event tree" approach has also been used by Gale (2003) to estimate risk from pathogen contamination of food crops. The scenario will be developed for various irrigation delivery systems (e.g., drip, furrow) and will focus on impacts to leafy greens, but may include additional crops (melons, carrots, peppers) depending upon the availability of data). Only surface contamination of the produce will be considered in the QMRA. While the industry is concerned with internalization of pathogens in produce, risk from such events will not be considered in this study. However, the QMRA scenarios developed in the current study could certainly be updated to include microbial internalization as more data becomes available. Estimate the risk of illness from ingestion of various levels of E.coli from the irrigation scenarios: Since the yearly consumption various produce in the United States is known, the yearly risk of illness from can be determined (Stine et al., 2005a).This can be modeled for each type of irrigation method and crop, and the information will be incorporated into graphics and/or simple programs to allow estimates of risk based on different scenarios. Usingcollected data we will estimate the level of risk from the E .coli and pathogens in the same water. While, we do not expect a direct correlation, we anticipate that these results will demonstrate that the relationship between E.coli and enteric pathogens can be conservatively estimated within a range in water quality found in irrigation waters. Monte Carlo simulations between likely and observed values will aid in identifying the relationships between the observed values and environmental parameters in the modeled scenarios, and how these relationships affect model outcomes and overall determination of risk. The simulations will also identify which parameters are most critical in determination of overall risk (Haas et al, 1991). The resulting output can be used to identify values of exposure or risk corresponding to a specified probability, say the 50th percentile or 95 percentile.

Progress 10/01/15 to 09/30/16

Outputs
Target Audience: Nothing Reported Changes/Problems: Nothing Reported What opportunities for training and professional development has the project provided? Nothing Reported How have the results been disseminated to communities of interest? Nothing Reported What do you plan to do during the next reporting period to accomplish the goals? Nothing Reported

Impacts
What was accomplished under these goals? Over the course of this study three datasets were gathered from the field by the authors and their students from irrigation canals at the Yuma and Maricopa, AZ and Imperial Valley, CA starting in 2001. The datasets have measurements of E. coli and coliforms counts per 100 ml of irrigation water and physical characteristics of the irrigation water. Supplemental datasets included pathogen presence information for some sampling locations and represented Salmonella, STEC, and enterococci data. Each region's dataset was analyzed separately to arrive at a regional model for prediction of E. coli and coliforms

Publications

Progress 10/01/14 to 09/30/15

Outputs
Target Audience:The primary beneficiaries of this project include but are not limited to the following; Fresh Produce Industry Food Safety Professionals Research Scientists The United States Environmental Protection Agency (USEPA) The Leafy Green Marketing Agreement (LGMA) FDA and Food Safety Modernization Act (FSMA) Yuma Fresh Produce Council Irrigation Districts Commercial testing labs Changes/Problems: Nothing Reported What opportunities for training and professional development has the project provided? Nothing Reported How have the results been disseminated to communities of interest?Workshops, presentations, online resources, personal communication. What do you plan to do during the next reporting period to accomplish the goals? Nothing Reported

Impacts
What was accomplished under these goals? Overall the research team was able to evaluate three currently used methods for the accurate assessment of E.coli in irrigation waters used for produce. Our concluding findings indicate that while all three methods are able to detect E.coli, the variance between them is great and that the IDEXX Colilert Quanti-Tray® seems to be the best choice when given an option. However, it is important to note that while the IDEXX Colilert Quanti-Tray® performed well at reducing False Positives rates, that False Negative rates were higher than the two other methods compared. This is important information for the industry and testing labs currently utilizing these methods for E.coli assessment. Additionally, through our comprehensive evaluation, a more robust QMRA analysis was performed using actual E.coli data collected throughout the growing region. This is the first study of this kind using actual environmental data and applying it to current regulatory guidelines for irrigation waters used for produce. The results of this risk assessment will be shared industry wide. To aid in information sharing, the final results of this project were presented at the Center for Produce Safety Produce Research Symposium in Rochester, NY in June, 2013 and to various extension clientele venues in 2015. Also, our team is currently working to finalize a Risk Communication Packet which contains a series "fact sheets" through the University of Arizona Cooperative Extension. This packet summarizes the research results but also includes sections on frequently asked questions, key message points, definitions regarding what are risk assessments, relative risk, and how water quality and irrigation risks compare to other risks commonly observed by the general population.

Publications

• Type: Theses/Dissertations Status: Published Year Published: 2015 Citation: Brassill, Natalie (2014) The Assessment of Escherichia coli as an Indicator of Microbial Quality of Irrigation Waters used for Produce; MS Thesis, The University of Arizona

Progress 10/01/13 to 09/30/14

Outputs
Target Audience: Food Safety Professionals Fresh Produce growers University research scientists Changes/Problems: Nothing Reported What opportunities for training and professional development has the project provided? Nothing Reported How have the results been disseminated to communities of interest? Outreach has included workshops to food safety professionals and other related stakeholders. Additionally, poster and oral presentations have been provided in locations across the US including the Center for Produce Safety annual research conference, International Association of Food Protection, and UA Food Safety Consortium. What do you plan to do during the next reporting period to accomplish the goals? Additional work will be done to improve the model by updating with real world water quality information. Additionally, project partners will work to disseminate information to appropriate stakeholder groups.

Impacts
What was accomplished under these goals? Summary of Findings and Recommendations. Results reveal E.coli in irrigation waters in all agricultural areas sampled, including exceedances of the LGMA guideline of 126 E.coli per 100 mL. All three methods have identified E.coli in irrigation waters, but methods including MI agar, and IDEXX Colilert Quanti-Tray®, have shown the most straightforward results for interpretation, while blue colonies on m-ColiBlue24® broth plates are typically not well defined, making it difficult to differentiate between a single colony or multiple colonies, which could over- or underestimate the E. coli in the sample. Our study indicates that there are significant differences between E. coli counts measured using m-ColiBlue24® and those measured using IDEXX Colilert Quanti-Tray®; and between those measured using IDEXX Colilert Quanti-Tray® and MI methods. However, there are no significant differences between E. coli counts measured using MI Agar and IDEXX Colilert Quanti-Tray®. The IDEXX Colilert Quanti-Tray® performed with the highest rate of accuracy with 49% of the time calling a true positive followed by MI Agar and m-ColiBlue24® broth at 33% and 29% respectively. Each of the three methods seemed to have elevated False Positive rates indicating the difficultly in accurately assessing E.coli concentrations. This could be due heavily to analyst interpretation and points towards the need in methods to be straight forward and user friendly. False positive rates ranged from 53% to 71% with m-ColiBlue24® broth performing the worst. According to the QMRA, if irrigation water has E. coli density of 126 per 100 ml (or 12.6 E. coli per 10 ml), and based on Stine et al. (2005), 0.00011 of the 126 E. coli per 100 ml (or 12.6 E. coli per 10 ml) will be transferred to lettuce for furrow irrigation system and 8.8 x 10-7 of the 126 will be transferred to lettuce for subsurface drip irrigation system. That corresponds to a risk of GI illness of 1.1 in 100,000 for furrows and 9 in 100,000,000 for subsurface irrigation system. For sprinkler irrigation system and based on Stine et al. (2011), 0.011 of the 126 E. coli per 100 ml (or 12.6 E. coli per 10 ml) will be transferred to lettuce resulting in a risk of GI illness of 1.1 in 1,000. Irrigation water containing 126 E. coli per 100 ml for lettuce would appear to present a minimal risk for furrow and subsurface drip. However, further research on contamination of lettuce by spray irrigation appears warranted to reduce uncertainty in the risk estimate.

Publications