Retrospective evaluation of an integrated molecular-epidemiological approach to cyclosporiasis outbreak investigations – United States, 2021

Lauren Ahart*: Affiliation:
Division of Parasitic Diseases and Malaria, Center for Global Health, Centers for Disease Control and Prevention, Atlanta, GA, USA
David Jacobson*: Affiliation:
Division of Parasitic Diseases and Malaria, Center for Global Health, Centers for Disease Control and Prevention, Atlanta, GA, USA Oak Ridge Institute for Science and Education, Oak Ridge, TN, USA
Marion Rice: Affiliation:
Division of Parasitic Diseases and Malaria, Center for Global Health, Centers for Disease Control and Prevention, Atlanta, GA, USA
Travis Richins: Affiliation:
Division of Parasitic Diseases and Malaria, Center for Global Health, Centers for Disease Control and Prevention, Atlanta, GA, USA Oak Ridge Institute for Science and Education, Oak Ridge, TN, USA
Anna Peterson: Affiliation:
Division of Parasitic Diseases and Malaria, Center for Global Health, Centers for Disease Control and Prevention, Atlanta, GA, USA Oak Ridge Institute for Science and Education, Oak Ridge, TN, USA
Yueli Zheng: Affiliation:
Division of Parasitic Diseases and Malaria, Center for Global Health, Centers for Disease Control and Prevention, Atlanta, GA, USA Eagle Global Scientific, San Antonio, TX, USA
Joel Barratt: Affiliation:
Division of Parasitic Diseases and Malaria, Center for Global Health, Centers for Disease Control and Prevention, Atlanta, GA, USA
Vitaliano Cama: Affiliation:
Division of Parasitic Diseases and Malaria, Center for Global Health, Centers for Disease Control and Prevention, Atlanta, GA, USA
Yvonne Qvarnstrom: Affiliation:
Division of Parasitic Diseases and Malaria, Center for Global Health, Centers for Disease Control and Prevention, Atlanta, GA, USA
Susan Montgomery: Affiliation:
Division of Parasitic Diseases and Malaria, Center for Global Health, Centers for Disease Control and Prevention, Atlanta, GA, USA
Anne Straily: Affiliation:
Division of Parasitic Diseases and Malaria, Center for Global Health, Centers for Disease Control and Prevention, Atlanta, GA, USA
*: Corresponding authors: David Jacobson and Lauren Ahart; Emails: quh7@cdc.gov; nox7@cdc.gov
Corresponding authors: David Jacobson and Lauren Ahart; Emails: quh7@cdc.gov; nox7@cdc.gov

Article contents

Abstract
Background
Methods
Results
Discussion
Data availability statement
Author contribution
Financial support
Competing interest
Disclaimer
Footnotes
References

Rights & Permissions

Abstract

Cyclosporiasis results from an infection of the small intestine by Cyclospora parasites after ingestion of contaminated food or water, often leading to gastrointestinal distress. Recent developments in temporally linking genetically related Cyclospora isolates demonstrated effectiveness in supporting epidemiological investigations. We used ‘temporal-genetic clusters’ (TGCs) to investigate reported cyclosporiasis cases in the United States during the 2021 peak-period (1 May – 31 August 2021). Our approach split 655 genotyped isolates into 55 genetic clusters and 31 TGCs. We linked two large multi-state epidemiological clusters (Epidemiologic Cluster 1 [n = 136 cases, 54 genotyped] and Epidemiologic Cluster 2 [n = 42 cases, 15 genotyped]) to consumption of lettuce varieties; however, product traceback did not identify a specific product for either cluster due to the lack of detailed product information. To evaluate the utility of TGCs, we performed a retrospective case study comparing investigation outcomes of outbreaks first detected using epidemiological methods with those of the same outbreaks had TGCs been used to first detect them. Our study results indicate that adjustments to routine epidemiological approaches could link additional cases to epidemiological clusters of cyclosporiasis. Overall, we show that CDC’s integrated genotyping and epidemiological investigations provide valuable insights into cyclosporiasis outbreaks in the United States.

Keywords

Molecular epidemiology Food-borne infections Cyclospora

Type: Original Paper
Information: Epidemiology & Infection , Volume 151 , 2023 , e131

DOI: https://doi.org/10.1017/S0950268823001176 [Opens in a new window]
Creative Commons: This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright: © The Author(s), 2023. Published by Cambridge University Press

Background

More than 1400 laboratory-confirmed cases of cyclosporiasis were reported to the U.S. Centers for Disease Control and Prevention (CDC) in each of 2018, 2019, and 2020, reflecting an increase in cyclosporiasis incidence since 2015 [Reference Barratt, Ahart, Rice, Houghton, Richins, Cama, Arrowood, Qvarnstrom and Straily1–Reference Nascimento, Barratt, Houghton, Plucinski, Kelley, Casillas, Bennett, Snider, Tuladhar, Zhang, Clemons, Madison-Antenucci, Russell, Cebelinski, Haan, Robinson, Arrowood, Talundzic, Bradbury and Qvarnstrom3]. Cyclosporiasis infections occur after ingesting produce and/or water contaminated by Cyclospora [Reference Barratt, Shen, Houghton, Richins, SGH, Cama, Arrowood, Straily and Qvarnstrom4], resulting in a range of nonspecific symptoms including watery diarrhoea, loss of appetite, cramps, and bloating [Reference Almeria, Cinar and Dubey5]. Epidemiological investigations of cyclosporiasis outbreaks can be challenging due to an incubation period between consumption of contaminated produce and symptom onset that may last up to 2 weeks and intermittent remission/relapse of symptoms that may delay seeking care, and because Cyclospora often contaminates commonly consumed fresh produce that is served in mixtures with other produce (e.g., leafy greens, berries, and herbs) or as garnishes [Reference Almeria, Cinar and Dubey5]. These circumstances make it difficult for case patients to recall specific produce items consumed potentially weeks prior to interview by a public health official, which hinders traceback investigations due to lack of highly detailed exposure information (i.e., product brand names). Sensitive molecular tools that identify clusters of genetically related Cyclospora infections could abate these challenges by allowing epidemiological follow-up investigations to focus on case patients infected with Cyclospora, or a closely related Cyclospora strain, which should increase the likelihood of uncovering the suspect food vehicle [Reference Chen, Brown, Knabel, Wiedmann and Zhang6].

The CDC uses the Cybernetic Clustering Of Nonclonal Eukaryotes (CYCLONE) bioinformatic workflow [Reference Barratt, Houghton, Richins, Straily, Threlkel, Bera, Kenneally, Clemons, Madison-Antenucci, Cebelinski, Whitney, Kreil, Cama, Arrowood and Qvarnstrom2] to identify infections caused by genetically related Cyclospora isolates. CYCLONE identifies genetic clusters with a ‘haplotype-based’ approach due to high heterozygosity and genetic complexities found in Cyclospora isolates [Reference Barratt, Park, Nascimento, Hofstetter, Plucinski, Casillas, Bradbury, Arrowood, Qvarnstrom and Talundzic7]. Previous studies have evaluated CYCLONE’s performance by comparing the composition of genetic clusters to analogous epidemiological clusters, the latter being used as a set of expected clustering outcomes [Reference Barratt, Ahart, Rice, Houghton, Richins, Cama, Arrowood, Qvarnstrom and Straily1, Reference Nascimento, Barratt, Houghton, Plucinski, Kelley, Casillas, Bennett, Snider, Tuladhar, Zhang, Clemons, Madison-Antenucci, Russell, Cebelinski, Haan, Robinson, Arrowood, Talundzic, Bradbury and Qvarnstrom3]. These evaluations demonstrate that genetic clusters produced by CYCLONE have over 96% agreement with epidemiological clusters. CYCLONE has been historically used to support the existence of epidemiologically identified outbreaks by demonstrating genetic relationships among isolates from case patients linked within an epidemiological cluster [Reference Nascimento, Barratt, Houghton, Plucinski, Kelley, Casillas, Bennett, Snider, Tuladhar, Zhang, Clemons, Madison-Antenucci, Russell, Cebelinski, Haan, Robinson, Arrowood, Talundzic, Bradbury and Qvarnstrom3]. Starting in 2020, the CDC began to use temporal information to prioritise genetically defined clusters for epidemiological follow-up. Temporal-genetic clusters (TGCs) are informative because produce items contaminated with Cyclospora are likely to be sources of infection for a limited range of time, rather than sporadically over many months, due to the limited shelf-life of fresh produce.

Genetic clustering data are used to inform epidemiological investigations in a variety of applications [Reference Riley and Blanton8], and PulseNet has used this approach to identify foodborne and waterborne outbreaks in the United Stated for over 20 years [Reference Swaminathan, Barrett, Hunter and Tauxe9]. In practice, the PulseNet model of outbreak investigation triggers epidemiological investigations after the identification of illness clusters caused by genetically similar pathogen isolates. Short laboratory turnaround times are critical for detecting clusters as long delays may make it difficult for epidemiologists to identify common exposures. Recent developments have shortened the processing time of whole genome sequencing (WGS), leading to improved genetic resolution generated in a similar time to pulse field gel electrophoresis [Reference Kubota, Wolfgang, Baker, Boxrud, Turner, Trees, Carleton and Gerner-Smidt10–Reference Carleton and Gerner-Smidt12]. Currently, cyclosporiasis investigations do not follow the PulseNet model because epidemiological investigations do not solely rely on the identification of a genetic cluster. We believe there is value in assessing how cyclosporiasis outbreak investigations would fit into a PulseNet approach, which may improve the integration of CYCLONE’s genetic clustering outputs with epidemiological investigations.

The objective of this study was to retrospectively investigate how the PulseNet outbreak investigation model might have performed had it been applied during the 2021 U.S. cyclosporiasis peak-period. This analysis represents an important step in determining whether an approach that uses genetic data to lead epidemiological follow-up (i.e., the PulseNet model) would benefit cyclosporiasis outbreak investigations. Ultimately, these results will help determine how operationalisation of Cyclospora genotyping data can improve future cyclosporiasis outbreak investigations and facilitate the translation of genotyping data into actionable public health recommendations.

Methods

Two-step analysis approach

We first detail the genetic clustering results and describe the relationship between TGCs and epidemiological clusters in 2021, with a focus on the two largest TGCs (2021_003 and 2021_005) and two multi-state epidemiological clusters (Epidemiologic Cluster 1 and Epidemiologic Cluster 2). Second, we focus our retrospective epidemiological investigations on a subset of isolates possessing identical genotypes to explore how a genetics-first approach, similar to PulseNet, would perform in cyclosporiasis investigations.

Faecal isolates

U.S. state health departments (SHDs) submitted stool specimens from laboratory-confirmed Cyclospora-positive case patients to the CDC for genotyping. Upon receipt at the CDC, the specimens were de-identified and given a unique identifier. DNA was extracted from the stool specimens following previously described methods [Reference Qvarnstrom, Benedict, Marcet, Wiegand, Herwaldt and da Silva13], and isolates with a Ct value greater than 38 after quantitative polymerase chain reaction (qPCR) targeting the Cyclospora 18S rRNA gene [Reference Qvarnstrom, Benedict, Marcet, Wiegand, Herwaldt and da Silva13] were excluded from downstream laboratory processing as isolates with Ct > 38 are highly unlikely to yield genotypes that pass CYCLONE’s inclusion criteria (Supplementary Material). In the remaining isolates, eight Cyclospora genotyping markers were PCR-amplified and sequenced following previously described methods [Reference Nascimento, Barratt, Houghton, Plucinski, Kelley, Casillas, Bennett, Snider, Tuladhar, Zhang, Clemons, Madison-Antenucci, Russell, Cebelinski, Haan, Robinson, Arrowood, Talundzic, Bradbury and Qvarnstrom3]. New York and Texas SHDs, along with the Public Health Agency of Canada (PHAC), generated sequencing data in-house following the protocols described earlier and submitted their data to the CDC to be analysed in CYCLONE. CYCLONE genotyping is detailed in the Supplementary Material.

Cluster identification using the CYCLONE workflow

Genotyped isolates must meet the following inclusion criteria to be included in clustering analysis: haplotypes identified in any combination of 5 of the 8 markers, or haplotypes from 4 markers if at least 3 of those 4 were CYCLONE’s high-entropy markers [Reference Barratt, Houghton, Richins, Straily, Threlkel, Bera, Kenneally, Clemons, Madison-Antenucci, Cebelinski, Whitney, Kreil, Cama, Arrowood and Qvarnstrom2, Reference Barratt and Sapp14]. Distance matrix calculation for the isolates passing the inclusion criteria (n = 655) was performed alongside a genetically diverse reference population of 1169 genotypes generated between 2018 and 2020 [Reference Barratt, Ahart, Rice, Houghton, Richins, Cama, Arrowood, Qvarnstrom and Straily1–Reference Nascimento, Barratt, Houghton, Plucinski, Kelley, Casillas, Bennett, Snider, Tuladhar, Zhang, Clemons, Madison-Antenucci, Russell, Cebelinski, Haan, Robinson, Arrowood, Talundzic, Bradbury and Qvarnstrom3]. Cluster membership of isolates was determined using a recently described statistical framework for genetically linking pairs of isolates and applying a stringency setting of 99.5% [Reference Plucinski and Barratt15]. Descriptions of the algorithms underpinning distance matrix calculation and genetic clustering are provided in the Supplementary Material. Isolates in the same genetic cluster were temporally linked by examining collection dates of each specimen to identify TGCs [Reference Barratt, Ahart, Rice, Houghton, Richins, Cama, Arrowood, Qvarnstrom and Straily1]. Initial TGCs are created when three or more isolates within the same genetic cluster originate from two or more jurisdictions, and the isolates have collection dates within fourteen days of each other; isolates are added to an existing TGC if they have collection dates that fall within seven days of the most recently collected isolate in the TGC. The hierarchically clustered tree was visualised using the GGTREE R package [Reference Yu, Smith, Zhu, Guan and Tsan-Yuk Lam16, 17].

Epidemiological data collection and cluster investigations

Epidemiological data received by the CDC primarily consist of responses to the Cyclosporiasis National Hypothesis Generating Questionnaire (CNHGQ), or state-adapted versions of the CNHGQ, which are used by epidemiologists at SHDs to interview case patients. The CNHGQ captures the clinical history, travel history, produce exposures, and information on where produce items were purchased or consumed. The CDC focused investigations on reported cases with no history of international travel during the 14 days prior to the illness onset during the U.S. cyclosporiasis peak-period, meaning that their illness was likely acquired within the United States (i.e., domestically acquired cases).

Epidemiological data reported via the CNHGQ were matched to genotyped isolates by case ID and analysed to detect emerging epidemiological clusters. We noted commonalities in produce exposures, grocery stores, or restaurants reported by 50% or more of case patients in a TGC. This analysis allowed us to focus investigation efforts on the most likely contaminated produce commodity, recognising that many fresh produce items included in the CNHGQ follow a seasonal pattern and are commonly consumed during the summer months. Data completeness was also assessed, and requests were made to the appropriate SHD if pertinent epidemiological data were missing (i.e., CNHGQ and/or Case ID). TGCs with over 50% of case patients reported as lost to follow-up (i.e., SHD was not able to complete an interview) were considered to have an insufficient amount of data for epidemiological review. Finally, we excluded case patients who reported history of international travel during the 14 days prior to the illness onset. Throughout the article, we use capital letters to signify epidemiologic clusters (e.g., Epidemiologic Cluster 1) and lowercase letters to signify epidemiologic exposures (e.g., lettuce type 1).

Examination of epidemiological links among isolates with identical genotypes: PulseNet model Case Study

We selected isolates from a subset of genetic clusters to assess how genotyping data could be used to guide epidemiological investigations. First, we filtered out any genetic clusters with less than two epidemiologically linked isolates. Next, we identified and retained genetically identical isolates within the remaining genetic clusters by comparing each isolate’s genotype to the consensus genotype for the genetic cluster. The consensus genotype consists of every haplotype found in over 50% of all isolates within a genetic cluster. We then analysed epidemiological data for completeness and excluded isolates with missing associated epidemiological data. Finally, we compared produce exposures for genetically identical isolates within each cluster to existing epidemiological clusters.

Results

Cyclosporiasis peak-period summary

Between 1 May and 31 August 2021, the CDC was notified of 1123 laboratory-confirmed cyclosporiasis cases from 36 U.S. states and New York City. Data from 797 isolates were submitted to the CDC for genotyping: 502 isolates were sequenced at the CDC and 295 were isolates sequenced by domestic and international partner laboratories. Genotypes were obtained from 655 of the 797 isolates, which were distributed across 55 genetic clusters (Figure 1). Isolates that did not yield a genotype (n = 142) either did not pass the qPCR inclusion criteria (n = 68) or did not have haplotypes identified in a sufficient combination of markers to pass the inclusion criteria (n = 74). A total of 44 TGCs were detected during the peak-period; however, 13 TGCs dissolved due to shifts in genetic cluster membership as new genotypes were added to the dataset each week (this phenomenon is discussed elsewhere [Reference Barratt, Ahart, Rice, Houghton, Richins, Cama, Arrowood, Qvarnstrom and Straily1]). This resulted in 561 isolates belonging to 31 distinct TGCs spread across 23 genetic clusters at the end of 2021 (two or more TGCs were found in seven genetic clusters).

Figure 1. Tree representing genetic cluster memberships.

Each colour on the inner ring represents a distinct genetic cluster. The specimens highlighted in purple in the outer ring are from 2021, and the specimens highlighted in white in the outer ring are reference specimens from 2018 to 2020. The locations of TGC 2021_003 (Genetic Cluster 18) and TGC 2021_005 (Genetic Cluster 11) are annotated by text boxes. Genetic cluster 18 contains TGC 2020_001 from 2020, which was linked to the bagged salad mix outbreak.

Fourteen of the 31 (45%) TGCs identified contained insufficient case data (Table 1) for epidemiological review, and all but one (2021_007) of the TGCs with insufficient data possessed six or fewer isolates. Fifty-nine isolates belonged to TGC 2021_007, yet over half of case patients within this TGC (n = 36, 61%) reported a history of international travel, were lost to follow-up, or missing pertinent information (Table 1). The remaining TGCs with sufficient epidemiological data available to review (n = 17, 55%) varied in size, and 10 of 17 (59%) TGCs were associated with epidemiological clusters (Table 1). Findings from a secondary retrospective analysis of the most commonly reported food exposures across all 17 TGCs showed that case patients who reported cucumber, tomatoes, or berries also reported consuming a salad, suggesting that herbs, cucumbers, tomatoes, and berries may have been consumed with a leafy green product. Of the 17 TGCs with sufficient epidemiological data to review, 14 TGCs included case patients who reported a history of international travel, were lost to follow-up, or missing epidemiological data (Table 1).

Table 1. All TGCs detected in the 2021 cyclosporiasis peak-period

Abbreviations: TGC, temporal-genetic cluster; CNHGQ, Cyclosporiasis National Hypothesis Generating Questionnaire.

^a Cyclosporiasis national hypothesis generating questionnaire.

^b Not available.

^c Isolates submitted by the public health agency of Canada.

Cyclosporiasis epidemiologic cluster investigations

In 2021, two major multi-state epidemiological clusters were investigated: Epidemiologic Cluster 1 and Epidemiologic Cluster 2. The Epidemiologic Cluster 1 investigation began in July following a notice from epidemiologists at SHDs that several case patients reported a specific lettuce type (lettuce type 1) from a single product brand. CDC epidemiologists used preliminary findings provided by state partners to analyse data reported via the CNHGQ; two different types of lettuce emerged as suspect vehicles after a thorough review of all leafy green exposures reported by case patients. A single product brand (or affiliated brands) was more frequently named by case patients who reported lettuce type 1; thus, we defined Epidemiologic Cluster 1 cluster to include only case patients reporting lettuce exposure from this product brand or an affiliate brand. Epidemiologic Cluster 1 consisted of 136 case patients from 20 states. Most case patients resided in the northeastern and midwestern regions of the United States. A total of 54 (40%) case patients in Epidemiologic Cluster 1 had a successfully genotyped isolate, and those isolates were associated with multiple genotypes and nine different TGCs (Table 2); however, half of the isolates belonged to TGC 2021_005 (n = 27, 50%).

Table 2. Multi-state epidemiological clusters identified in 2021 and their associations with identified TGCs

Abbreviations: TGC, temporal-genetic cluster.

^a A dual exposure was defined as a reported exposure to both lettuce type 1 and lettuce type 2.

^b Identical to the consensus genotype of their respective TGC.

^c Not available.

Epidemiologic Cluster 2 was identified in August after CDC epidemiologists noted the emergence of a second lettuce type (lettuce type 2) that had not been previously reported by U.S. cyclosporiasis case patients. Lettuce type 2 did not appear to be associated with a particular product brand, and most case patients epidemiologically linked to Epidemiologic Cluster 2 resided in the southern United States. In total, 42 case patients were epidemiologically linked across 10 states. A total of 15 (36%) case patients in Epidemiologic Cluster 2 had a successfully genotyped isolate (Table 2). This cluster was associated with two TGCs (2021_003 and 2021_034), but 87% of epidemiologically linked cases (n = 13) were assigned to TGC 2021_003 (Table 2). The genetic cluster containing TGC 2021_003 possessed reference genotypes from isolates previously linked to a bagged salad mix outbreak from 2020 [Reference Barratt, Ahart, Rice, Houghton, Richins, Cama, Arrowood, Qvarnstrom and Straily1] (Figure 1). However, case patients epidemiologically linked to the 2020 bagged salad mix outbreak did not report the same lettuce exposure as case patients in the 2021 Lettuce 2 cluster.

Five case patients with successfully genotyped isolates reported exposures to both lettuce type 1 and lettuce type 2 (i.e., ‘dual exposures’). CDC epidemiologists linked these case patients to either Epidemiologic Cluster 1 or Epidemiologic Cluster 2 based on similarity to genotypes within a TGC and case patients’ geographical clustering with other case patients who already had been epidemiologically linked to Epidemiologic Cluster 1 or Epidemiologic Cluster 2 (Table 2). Notably, the four case patients with dual exposures within TGCs 2021_005 and 2021_006 reported purchasing lettuce type 1 from four distinct grocery stores.

In addition to the two multi-state outbreaks, epidemiologists at SHDs in eight states identified nine other single-state epidemiological clusters, yielding a total of 228 laboratory-confirmed cyclosporiasis cases linked to an epidemiological cluster. Of these, 84 cases had isolates that were successfully genotyped. The CDC received at least one specimen for genotyping from case patients associated with six of the nine clusters, and all genotyped isolates belonging to the same single-state epidemiological cluster also belonged to the same TGC.

Epidemiological investigation of isolates with an identical genotype: the PulseNet model case study

The retrospective PulseNet model analysis focused on isolates with identical genotypes within the two TGCs that had the majority of isolates linked to Epidemiologic Cluster 1 and Epidemiologic Cluster 2 to determine whether additional isolates could be linked to these epidemiological clusters. After excluding isolates as described in the Methods, 185 isolates met the inclusion criteria for our PulseNet model case study. This analysis allowed us to investigate why these case patients were not linked to an epidemiological cluster despite their genetic similarity to isolates from other case patients epidemiologically linked to a cluster.

Within TGC 2021_003, 53 of 129 (41%) genotypes were identical to the consensus genotype. Of the 53 isolates with an identical genotype, 11 (21%) were from case patients linked to Epidemiologic Cluster 1 (n = 2), Epidemiologic Cluster 2 (n = 8), and Local Cluster 1 (n = 1) (Table 3). The remaining identical genotypes in TGC 2021_003 (n = 42, 78%) could not be epidemiologically linked to a cluster due to one of the following reasons: missing epidemiological data (n = 6, 14%), reported history of international travel (n = 3, 7%), lack of product information (n = 14, 33%), or failure to meet the epidemiological cluster inclusion criteria (n = 19, 45%) (Table 3). In summary, the primary reasons for not linking the remaining case patients to Epidemiologic Cluster 1 or Epidemiologic Cluster 2 in TGC 2021_003, despite the genetically identical genotypes, were the lack of detailed product information available (i.e., brand name) or case patients failed to meet the epidemiological cluster inclusion criteria. The single isolate in TGC 2021_003 with dual epidemiological exposures did not have a complete genotype, so it was excluded from the analysis of identical genotypes.

Table 3. Primary TGCs and epidemiological cluster classifications

Abbreviations: TGC, temporal-genetic cluster.

^a Not available.

A total of 46 isolates with identical genotypes were identified in TGC 2021_005. Of these, 21 (46%) case patients were associated with Epidemiologic Cluster 1, while the remaining 25 (54%) case patients could not be epidemiologically linked to a cluster (Table 3). Two case patients (8%) were missing epidemiological information, 8 (32%) lacked product information, and 15 (60%) failed to meet the epidemiological inclusion criteria (Table 3). Three case patients in TGC 2021_005 reported exposures to both lettuce type 1 and lettuce type 2 but were linked to epidemiological clusters based on their isolate’s genotype: two had an identical genotype to other isolates in 2021_005 and were linked to Epidemiologic Cluster 1, while the remaining isolate did not have data from all eight genotyping markers and was excluded from the identical genotype analysis.

Discussion

Rapid and effective public health response to cyclosporiasis outbreaks can be improved with a better understanding of how cases are linked, both genetically and epidemiologically. The primary objective of this study was to evaluate an approach that has the potential to enhance identification and investigation of cyclosporiasis clusters by prioritising Cyclospora isolates with identical genotypes. This two-step procedure first identified isolates in TGCs that belonged to the same epidemiological cluster and then retrospectively analysed genetically identical isolates in a subset of genetic clusters to see if additional epidemiologically linked isolates could be identified.

Nearly half of all cases linked to TGCs either reported international travel during the 2-week incubation period when exposures would have likely occurred or lacked pertinent epidemiological data (i.e., missing CNHGQ and/or Case ID), making it difficult to link case patients to epidemiological clusters. In some instances, epidemiological data were available, but investigations remained challenging due to the high number of case patients reporting more than one fresh produce exposure. Nevertheless, we focused on leafy green exposures as most other fresh produce items were rarely reported without a leafy green co-exposure.

Isolates linked to the two leafy green-associated multi-state epidemiological clusters primarily belonged to the two largest TGCs identified in 2021 (Epidemiologic Cluster 1: 2021_005 and Epidemiologic Cluster 2: 2021_003); however, nine different TGCs were identified among case patient isolates associated with Epidemiologic Cluster 1, suggesting that either a single lettuce product might have been contaminated with multiple strains of Cyclospora, or that multiple lettuce products might have been contaminated with different strains of Cyclospora. Product traceback investigations for commonly consumed food items remain difficult to conclude, especially without specific epidemiological data. Thus, the exact contamination scenario of Epidemiologic Cluster 1 could not be determined. Nearly all epidemiologically linked isolates in Epidemiologic Cluster 2 were assigned to the same TGC (2021_003), yet, similar to Epidemiologic Cluster 1, product traceback investigations were inconclusive. Several case patients epidemiologically linked to Epidemiologic Cluster 2 cluster reported shopping at a single grocery store chain that did not have a shopper card system. Investigators find shopper card records (i.e., receipts) useful to gather information on the types or brands of produce purchased by case patients. These records are particularly useful for cyclosporiasis investigations where the time between consumption of a product and interview by local or state health departments is weeks or even months after potential exposure, which can affect a person’s ability to accurately recall what they ate or retrieve any purchase information for foods consumed. Without product information, product traceback investigations are hindered, and it is difficult to identify a single producer, as was the case for Epidemiologic Cluster 2.

The identical genotype retrospective study provided insights regarding why certain case patients were not linked to an epidemiological cluster. These data are important for understanding how using the genotyping data as a primary trigger for conducting epidemiological investigations (i.e., the PulseNet model) would impact cyclosporiasis investigations. We found most case patients could not be epidemiologically linked to a cluster because of incomplete epidemiological data, recent international travel, not specifying a product brand for produce exposures, or exposure to a produce item not associated with a known epidemiological outbreak. This pilot analysis indicates that starting analyses with TGCs would have likely resulted in similar epidemiological cluster membership compared to the approach currently used by CDC epidemiologists as case patients cannot be linked to an epidemiological cluster without sufficient epidemiological data. However, using a PulseNet approach to investigate these clusters might have resulted in more complete epidemiological data because secondary case patient interviews would have been conducted after identification of genetic linkages, and supplemental questionnaires could have been used to target specific brands or produce exposures.

An important caveat to using genetic data to trigger epidemiological investigations is the time between initial diagnosis of Cyclospora infection, receipt of faecal specimens at the CDC, and determination of genotyping results. CDC laboratory turnaround time is less than 10 days, but some of this process is highly variable and could impact real-time cluster detection as a result. In addition, the lag between the consumption of a contaminated produce item, onset of symptoms, sample collection, and submission to the CDC could be several weeks; thus, it is important that SHDs still perform epidemiologic investigations while genetic data are analysed at the CDC in order to maximise case patients’ dietary recall. Subsequently, exploratory interviews should be conducted on a subset of case patients within each TGC (i.e., after genotyping) to gather specific information on product brands. This two-pronged approach maintains the current practice of gathering epidemiologic data soon after diagnosis, while also implementing a PulseNet-like approach, where a subset of case patients are interviewed after genetic clustering is complete. We believe such a model would enhance traceback investigations via the collection of more detailed information from case patients.

Epidemiological data remain necessary for identifying the source of cyclosporiasis outbreaks as relying solely on Cyclospora genetic data can limit investigations. For example, not all laboratory-confirmed cases of cyclosporiasis have a specimen sent to the CDC for genotyping and some isolates do not yield a useable genotype, both of which contribute to an underrepresentation of the true number of outbreak cases. Moreover, epidemiological data are typically available to review before genetic data are processed, and epidemiologists at SHDs often identify an epidemiological cluster before isolates or sequence data are submitted to the CDC (e.g., during interviews with case patients). Perhaps most importantly, genetic clustering results alone are of limited value; to become actionable (e.g., to initiate a product recall), a common food vehicle must be identified through an epidemiological investigation. Efforts to improve epidemiological data collection and enhance epidemiological investigations are ongoing. Most recently, CDC epidemiologists revised the CNHGQ (version 3.4) to include supplementary questions that capture additional details about leafy green products [Reference Barratt, Ahart, Rice, Houghton, Richins, Cama, Arrowood, Qvarnstrom and Straily1, Reference Barratt, Houghton, Richins, Straily, Threlkel, Bera, Kenneally, Clemons, Madison-Antenucci, Cebelinski, Whitney, Kreil, Cama, Arrowood and Qvarnstrom2]. Additionally, a new, stand-alone question regarding the suspect vehicle identified in Epidemiologic Cluster 2 was added to the CNHGQ; historically, this exposure was rarely reported by cyclosporiasis cases but warranted further consideration following the Epidemiologic Cluster 2 investigation. These revisions should allow for improved identification of specific produce items during outbreak investigations, which will in turn also help inform product traceback investigations led by the U.S. Food and Drug Administration (FDA).

In this study, we observed that most isolates genotyped from case patients associated with the two multi-state epidemiological clusters identified in 2021 belonged to one of the two major TGCs. About half of all genotyped isolates epidemiologically linked to Epidemiologic Cluster 1 were assigned to TGC 2021_005, while the remainder were distributed across multiple TGCs. The reason for this outcome is not clear; however, it might be due to case patients misremembering food exposures (i.e., reporting lettuce type 1 by mistake) or to the possibility that multiple sources of Cyclospora contaminated this type of produce during the U.S. cyclosporiasis peak-period. We cannot rule out the possibility that lettuce type 1 was merely identified as a suspect vehicle because it is commonly consumed during the cyclosporiasis peak-period, which highlights our call for enhanced epidemiological data collection. The analysis of isolates with an identical genotype allowed us to conclude that non-epidemiologically linked case patients with isolates genetically identical to genotypes of other epi-linked case patients were not misclassified, but rather could not be classified at all because they were missing epidemiological data, lacked sufficient details on produce exposures, or did not report the produce exposure of interest. Before the CYCLONE genetic clustering data can be operationalised like the PulseNet model, CDC epidemiologists would potentially need to adjust how cyclosporiasis clusters are defined and how case patients are interviewed. In summary, this study highlights the continued benefits of an integrated genetic and epidemiological investigation approach, while providing avenues to enhance public health investigations and response to cyclosporiasis outbreaks.

Supplementary material

The supplementary material for this article can be found at http://doi.org/10.1017/S0950268823001176.

Data availability statement

FASTQ sequence data for all isolates analysed in this study are available under NCBI BioProject PRJNA578931. Readers may contact the authors for access to the CYCLONE code used in this study’s bioinformatic analysis.

Acknowledgements

We are thankful to all state and international public health laboratories that submitted stool specimens and sequence data, which made genotyping possible. We appreciate the effort made by epidemiologists to submit epidemiological data in a timely matter.

Author contribution

D.J. prepared primary bioinformatic analysis, prepared figure, wrote the original draft, and reviewed/prepared final drafts; L.A. carried out epidemiological data curation and analysis, prepared tables, wrote the original draft, and reviewed/prepared final drafts; M.R. performed epidemiological data curation and analysis and reviewed and edited drafts; T.R. and A.P. performed wet lab work, helped with data generation, and reviewed and edited drafts; Y.Z. made improvements to bioinformatics workflow and reviewed and edited drafts; J.B. designed bioinformatic workflow, supported with analysis, and reviewed and edited drafts; and V.C., Y.Q., S.M., and A.S. helped with project conceptualisation, obtained funding, and edited and reviewed final drafts.

Financial support

This work was supported by the U.S. Centers for Disease Control and Prevention’s Advanced Molecular Detection (AMD) Initiative.

Competing interest

The authors declare no competing interest.

Disclaimer

The findings and conclusions in this report are those of the authors and do not necessarily represent the official position of the U.S. Centers for Disease Control and Prevention.

Footnotes

Lauren Ahart and David Jacobson contributed equally.

References

Barratt, J, Ahart, L, Rice, M, Houghton, K, Richins, T, Cama, V, Arrowood, M, Qvarnstrom, Y and Straily, A (2022) Genotyping Cyclospora cayetanensis from multiple outbreak clusters with an emphasis on a cluster linked to bagged salad mix - United States, 2020. Journal of Infectious Diseases 225(12), 2176–2180.CrossRef Google Scholar PubMed

Barratt, J, Houghton, K, Richins, T, Straily, A, Threlkel, R, Bera, B, Kenneally, J, Clemons, B, Madison-Antenucci, S, Cebelinski, E, Whitney, BM, Kreil, KR, Cama, V, Arrowood, MJ and Qvarnstrom, Y (2021) Investigation of US Cyclospora cayetanensis outbreaks in 2019 and evaluation of an improved Cyclospora genotyping system against 2019 cyclosporiasis outbreak clusters. Epidemiology & Infectection 149, e214.CrossRef Google Scholar PubMed

Nascimento, FS, Barratt, J, Houghton, K, Plucinski, M, Kelley, J, Casillas, S, Bennett, CC, Snider, C, Tuladhar, R, Zhang, J, Clemons, B, Madison-Antenucci, S, Russell, A, Cebelinski, E, Haan, J, Robinson, T, Arrowood, MJ, Talundzic, E, Bradbury, RS and Qvarnstrom, Y (2020) Evaluation of an ensemble-based distance statistic for clustering MLST datasets using epidemiologically defined clusters of cyclosporiasis. Epidemiology & Infection 148, e172.CrossRef Google Scholar PubMed

Barratt, JLN, Shen, J, Houghton, K, Richins, T, SGH, Sapp, Cama, V, Arrowood, MJ, Straily, A and Qvarnstrom, Y (2023) Cyclospora cayetanensis comprises at least 3 species that cause human cyclosporiasis. Parasitology 150(3), 269–285.CrossRef Google Scholar PubMed

Almeria, S, Cinar, HN and Dubey, JP (2019) Cyclospora cayetanensis and cyclosporiasis: An update. Microorganisms 7(9), 317.CrossRef Google Scholar PubMed

Chen, Y, Brown, E and Knabel, SJ (2011) Molecular epidemiology of foodborne pathogens. In Wiedmann, M and Zhang, W (eds.), Genomics of Foodborne Bacterial Pathogens. New York, NY: Springer, pp. 403–453.CrossRef Google Scholar

Barratt, JLN, Park, S, Nascimento, FS, Hofstetter, J, Plucinski, M, Casillas, S, Bradbury, RS, Arrowood, MJ, Qvarnstrom, Y and Talundzic, E (2019) Genotyping genetically heterogeneous Cyclospora cayetanensis infections to complement epidemiological case linkage. Parasitology 146(10), 1275–1283.CrossRef Google Scholar PubMed

Riley, LW and Blanton, RE (2018). Advances in molecular epidemiology of infectious diseases: Definitions, approaches, and scope of the field. Microbiology Spectrum 6(6), 6.6.01.CrossRef Google Scholar PubMed

Swaminathan, B, Barrett, TJ, Hunter, SB, Tauxe, RV and CDC PulseNet Task Force (2001) PulseNet: The molecular subtyping network for foodborne bacterial disease surveillance, United States. Emerging Infectious Diseases 7(3), 382–389.CrossRef Google Scholar

Kubota, KA, Wolfgang, WJ, Baker, DJ, Boxrud, D, Turner, L, Trees, E, Carleton, HA and Gerner-Smidt, P (2019) PulseNet and the changing paradigm of laboratory-based surveillance for foodborne diseases. Public Health Reports 134(2_suppl), 22S–28S.CrossRef Google Scholar PubMed

Salipante, SJ, DJ, SenGupta, Cummings, LA, Land, TA, Hoogestraat, DR, and Cookson, BT (2015) Application of whole-genome sequencing for bacterial strain typing in molecular epidemiology. Journal of Clinical Microbiology 53(4), 1072–1079.CrossRef Google Scholar PubMed

Carleton, HA and Gerner-Smidt, P (2016) Whole-genome sequencing is taking over foodborne disease surveillance. Microbe 11(7), 311–317.Google Scholar

Qvarnstrom, Y, Benedict, T, Marcet, PL, Wiegand, RE, Herwaldt, BL and da Silva, AJ (2018) Molecular detection of Cyclospora cayetanensis in human stool specimens using UNEX-based DNA extraction and real-time PCR. Parasitology 145(7), 865–870.CrossRef Google Scholar PubMed

Barratt, JL and Sapp, SG (2020). Machine learning-based analyses support the existence of species complexes for Strongyloides fuelleborni and Strongyloides stercoralis. Parasitology 147(11), 1184–1195.CrossRef Google Scholar PubMed

Plucinski, MM and Barratt, JLN (2021) Nonparametric binary classification to distinguish closely related versus unrelated plasmodium falciparum parasites. American Journal of Tropical Medicine and Hygiene 104(5), 1830–1835.CrossRef Google Scholar PubMed

Yu, G, Smith, DK, Zhu, H, Guan, Y and Tsan-Yuk Lam, T (2017) GGTREE: An R package for visualization and annotation of phylogenetic trees with their covariates and other associated data. Methods in Ecology and Evolution 8(1), 28–36.CrossRef Google Scholar

R Core Team (2013) R: A language and environment for statistical computing. In: R Foundation for Statistical Computing. https://www.R-project.org Google Scholar

Figure 1. Tree representing genetic cluster memberships.Each colour on the inner ring represents a distinct genetic cluster. The specimens highlighted in purple in the outer ring are from 2021, and the specimens highlighted in white in the outer ring are reference specimens from 2018 to 2020. The locations of TGC 2021_003 (Genetic Cluster 18) and TGC 2021_005 (Genetic Cluster 11) are annotated by text boxes. Genetic cluster 18 contains TGC 2020_001 from 2020, which was linked to the bagged salad mix outbreak.