Sampling sites and times

We sampled at 38 sites on 16 inland lakes in northwestern Michigan (Fig. 1, Table S1). Site locations were largely determined by stakeholder interest due to each lake individually funding the study on their lake. Despite this, these sites represented a range of lake sizes, shoreline types (e.g. beach vs marsh) and levels of human activity. Each sampling site was restricted to a 15 m stretch of shoreline and extended at least 15 m into the littoral zone (out to approximately 0.8 m depth) and 15 m into the riparian zone. We conducted all aquatic sampling within the limits of these zones. Before daily sampling began, 2 HOBO pendant temperature loggers (Onset Computer Corp., Bourne, MA, USA) and a marker buoy were installed at each site at 60 cm depth. Both loggers recorded hourly temperature readings, but 1 logger at each site also recorded hourly light intensity and was anchored to ensure the light sensor remained horizontal and facing upwards. We also placed periphyton samplers at this depth (see Supplemental Materials ‘Field survey methods – Periphyton growth’). One exception was Deer Lake, where the slope was too shallow that we decided to place equipment at only 45 cm depth to avoid going too far outside the 15 × 15 m sampling area. Daily community science sampling occurred during a 28-day period in July and August 2016, starting on July 5 (detailed below). Daily measurements started 2–3 weeks earlier at selected sites on Crystal Lake and Intermediate Lake based on individual lake support. Site visits and snail surveys started the week prior to this sampling period (the week of June 26) and occurred every 2 weeks at most sites (3 total surveys) and weekly at a few selected sites (at least 1 site at each lake; 5 total surveys).

Community science sampling – daily cercaria samples, weather and bird observations

Cercaria release into the environment is highly variable at a daily time scale for avian schistosomes (Soldánová et al., Reference Soldánová, Born-Torrijos, Kristoffersen, Knudsen, Amundsen and Scholz2022). Therefore, to capture a clear pattern of cercaria abundance at each site, we employed daily sampling utilizing a community science approach. Daily cercaria samples were collected by trained community science volunteers, who were provided with pre-labelled 15 mL centrifuge tubes, a 1 L pitcher, a custom-made 35 μm Nitex mesh filter (Fig. S1), a squirt bottle filled with tap water, another squirt bottle filled with 70% ethanol, a small funnel, and a stand to hold the filter during filtration (if necessary). Cercariae are likely to have aggregated distributions in the water, so to reduce the chances of missing small clumps of cercariae we sought to collect a distributed sample from each sampling site. We therefore asked volunteers to filter 24 separate 1-L scoops of water for each daily sample at each sampling site. Each morning, when Trichobilharzia spp. cercariae are released into the environment (~8:00–10:00 AM; Soldánová et al., Reference Soldánová, Selbach and Sures2016), volunteers entered the water near the left boundary of the site while holding the 1-liter pitcher and the Nitex mesh filter, haphazardly collecting water from the surface using the pitcher and pouring it through the filter as they moved in a zig-zag pattern throughout the littoral zone of the sampling site. Volunteers were allowed to collect their water samples in a bucket prior to filtration, allowing sediment to settle to the bottom of the bucket prior to decanting the water through the mesh filter. Avian schistosome cercariae typically move toward light and stay near the water surface (Cort and Talbot, Reference Cort and Talbot1936; Brachs and Haas, Reference Brachs and Haas2008), so they are unlikely to have been lost through this procedure. Once the lake water had been filtered, the squirt bottle containing tap water was used to rinse any residual material into 1 corner of the filter, followed by a final rinse with 70% ethanol to wash the sample into a 15 mL centrifuge tube using a small funnel. The use of 70% ethanol killed and preserved the DNA of any cercariae captured in the sample. Volunteers rinsed and back-rinsed their filters daily with tap water to keep the mesh clean. Samples were stored at room temperature until they were transported back to Oakland University at the end of the survey for further processing. Community science volunteers at each site were also encouraged to collect daily data describing weather conditions, air temperature, onshore wind speed and direction with the provided equipment. They were also asked to tally any sightings of birds within visual range of the study site.

qPCR quantification of avian schistosomes

After the survey was completed, we used qPCR to quantify the number of gene copies of avian schistosome DNA. Due to budgetary limitations, we developed a low-cost protocol for this process. Our protocol is like that of Rudko et al. (Reference Rudko, Reimink, Froelich, Gordy, Blankespoor and Hanington2018); however, we aimed to develop this protocol to be economical and scalable to a larger number of volunteer-collected samples. Briefly, we used a recently detailed protocol and custom primers that target a highly conserved region of 18S ribosomal RNA gene sequences specific to schistosome parasites (Jothikumar et al., Reference Jothikumar, Mull, Brant, Loker, Collinson, Secor and Hill2015). This assay only differentiates schistosomes vs non-schistosomes; we assumed that any amplified DNA largely belonged to the genus most associated with swimmer's itch in this geographic region, Trichobilharzia, though other SI-causing schistosomes from the genera Schistosomatium and Gigantobilharzia have also been observed in Michigan (Muzzall et al., Reference Muzzall, Burton, Snider and Coady2003; McPhail et al., Reference McPhail, Froelich, Reimink and Hanington2022; Rudko et al., Reference Rudko, McPhail, Reimink, Froelich, Turnbull and Hanington2022, Soper et al., Reference Soper, Raffel, Sckrabulis, Froelich, McPhail, Ostrowski, Reimink, Romano, Rudko and Hanington2023). We decided to divide each field sample in half prior to extraction, which we hoped would allow us to assess potential sources of error in the assay (i.e. extraction error vs qPCR error). For each field sample, we added together the qPCR estimates of cercaria abundance for the 2 extractions. qPCR data is typically lognormally distributed, so we log₁₀-transformed the daily cercaria estimates and averaged them to obtain log₁₀ cercaria abundance for each site. Log₁₀ cercaria abundance was used as our proxy for avian schistosome risk for all our among-site analyses. For a full description of this protocol, see the Supplementary Materials (‘Low-cost protocol for avian schistosome DNA detection’).

Habitat assessment

At the beginning of the sampling period, a team of Raffel Lab student researchers conducted a habitat assessment in the littoral zone (15 × 15 m in water) and the riparian zone (15 × 15 m on land) using a standardized checklist modelled after the Environmental Protection Agency's 2012 National Lakes Assessment protocol (EPA 841-B-11-003). For all components of the site assessment, a numerical score was used to indicate abundance of landscape or substrate types based on the following numeric index: 0 = Absent, 1 = Sparse (<10% coverage), 2 = Moderate (10 − 40% coverage), 3 = Heavy (40 − 75% coverage) and 4 = Very Heavy (>75% coverage). The riparian ground cover was observed, checking for the abundance of vegetation (woody shrubs, saplings, herbs and grasses) and barren areas (dirt/sand/rock). Riparian canopy and human influence were also classified and recorded. Habitat in the littoral zone was assessed by noting the presence/absence and abundance of various substrates (boulder, cobble, gravel, sand, muck) and types of aquatic vegetation (submergent, emergent, floating and total plant cover).

Visual quadrat surveys

Each site was visited 3–5 times to measure the abundance and diversity of aquatic snails within the littoral zone, which we divided into 3 depth areas (0–40 cm, 40–80 cm and >80 cm). PVC quadrat sampling frames (0.09 m²) were haphazardly tossed within each depth zone until a total of 4 frames were counted in each. A clear-bottom viewing bucket was used to observe and count the number of snails on the substrate within the boundaries of each frame. Densities were recorded for snails, visually identified to the genus level in the field. Densities of any other organisms (e.g. crayfish and mussels) present in a given quadrat were also recorded as they were encountered. Snails were also collected from throughout the littoral area and preserved in 70% ethanol to verify the proportion of snails from each species during 15-minute intensive targeted searches after quadrat sampling was completed during each visit. We computed several indices of snail abundance, including total abundance, and both individual densities of each snail type, and combined densities of Lymnaea, Planorbella and Physa snails as potential predictors of cercaria abundance.

Environmental variables

Alongside the visual quadrat surveys and timed snail collections conducted at the time of each visit, we also collected samples to assess other biotic and abiotic variables that might impact snail or cercaria presence (Fig. 1). We set out several sampling apparatuses to collect mussel settling rates and periphyton/biofilm formation. We collected water and sediment samples to assess water and sediment chemistry. We conducted multiple instances of crayfish trapping and zooplankton sampling. Lastly, we also assessed lake watershed land-use information using GIS. See the Supplementary Materials (‘Field survey methods’) for a full description of methods used for each of these variables.

Statistical analyses

To investigate possible relationships between environmental factors (abiotic and biotic) and host snail cercaria abundance, we took an analytical approach similar to that of Rohr et al. (Reference Rohr, Schotthoefer, Raffel, Carrick, Halstead, Hoverman, Johnson, Johnson, Lieske, Piwoni, Schoff and Beasley2008b), where we measured a large number of variables that could plausibly influence our system. There are potential risks of obtaining spurious low P values due to model over-fitting (overly complex models) or the presence of influential outliers in analyses that contain many potential predictors relative to sample size (n = 38 sites). We sought to reduce these risks by (1) sampling a large number of sites relative to prior studies in this region, (2) limiting the analysis of each response variable to seemingly plausible explanatory variables (Fig. 1), (3) log₁₀-transforming count variables and those with skewed distributions, (4) examining each statistical relationship graphically to ensure that it had a plausible directionality and was not driven by influential outliers and (5) limiting the size of individual models to a maximum of 5 predictors during model selection.

All data were aggregated to the site level (n = 38), using the average of each measured variable over the entire study period (e.g. average daily log₁₀ cercaria abundance over at least 1 month, or average log₁₀ snail density across at least 3 quadrat surveys). This resulted in all but a few predictor variables having complete data for all 38 sites (Table S3). We generated a correlation matrix to help identify pairwise relationships between variables, where relationships were considered strong candidates when the correlational statistic r was > 0.4 or < −0.4. A summary of all correlates with response variables of interest is presented in Table S2. We then used the program R (v4.3.1; R Core Team, Reference R Core Team2023) to conduct stepwise model selection to identify a set of likely predictor variables for each response variable (linear regression using the ‘regsubsets’ function in the package ‘leaps’; Lumley and Miller, Reference Lumley and Miller2020). A list of potential predictors included in the model for each response variable is provided in Table S3. To reduce chances of model over-fitting, we limited the maximum number of variables per ‘regsubsets’ model to 5 (nvmax = 5); because this function only returns models of the size specified, we sorted the list of models returned by the function by adjusted R ² to assess model fit and predictor inclusion in the model. This generated a set of up to 5 potentially important predictor variables for each response variable. We conducted 2 versions of this analysis for each response variable that included temperature variables as hypothesized predictors, 1 with and 1 without including these predictors, due to missing temperature data from 1 site.

We then combined the top predictor variables identified as potentially important from either ‘regsubsets’ output (between 4 and 9 predictors) into a single model and used manual backward selection to remove non-significant predictors via F-tests (P < 0.05). We also considered predictors for possible removal if the effect direction was opposite of the hypothesized effect (see Fig. 2); these were examined on a case by case basis (see Discussion). At this stage, we added 1 additional hypothesized predictor to each relevant model that was not included in the ‘regsubsets’ output due to missing data from 1 site (sediment phosphorus; Table S3), assessed its significance, and again simplified the model via backward selection.

Although most predictor variables in this analysis were measured at the level of individual sites, some predictors had only a single value for each lake (e.g. maximum lake depth). We therefore sought to account for potential random effects of Lake in our analysis. The ‘regsubsets’ function only supports linear regression models (i.e. no random effects), and methods allowing for automated stepwise or all-subsets selection of mixed effects models are computationally intensive (e.g. the ‘dredge’ function in the package ‘MuMIn’; Bartón, Reference Bartón2019). We therefore added a random effect of ‘Lake’ to each final model, to guard against variable inclusion due to pseudoreplication (generalized linear mixed effects models using the ‘lmer’ function in the package ‘lme4’; Bates et al., Reference Bates, Maechler, Bolker and Walker2015). Once we had a final mixed effect model for each response variable (presented in Tables 2 & S4), we tested for spatial confoundment by adding main effects of latitude and longitude to each model, followed by another round of backward selection. If a predictor was kicked out by adding either latitude or longitude to the model, we considered it a spatially confounded predictor.

We verified the robustness of our core model outputs by also utilizing the ‘exhaustive’ method within the ‘regsubsets’ function to conduct an all-subsets analysis for each of the response variables presented in Table 2, again with nvmax = 5. We examined the top 10 models for each response variable in order of adjusted R ². All-subsets model outputs can be difficult to interpret in analyses containing clusters of highly correlated predictor variables, but this method is less prone to variable ‘trapping’ than stepwise selection procedures. Here we used all-subsets to confirm that each of the primary predictors from our core models, or a closely related predictor, appeared in all or most of the top 10 models for each response variable.

Table 2. Final models for each response variable of interest, following stepwise model selection

All final models included ‘Lake’ as a random effect. Note that the ‘Anova’ function from the ‘car’ package uses the Kenwood-Roger approximation for estimating degrees of freedom for F-tests, which can result in non-integer values (Fox and Weisberg, Reference Fox and Weisberg2019).

^a Variable with missing data (one missing datapoint for sediment phosphorus)

^b Lake-level variable

^c Buildings became non-significant when Longitude was added to the final model (spatial autocorrelation)

In general, we are more confident of results where (1) the final model was relatively simple (i.e. 3 or fewer significant predictors), (2) predictors present in the top model were also among the top single correlates of a given response variable, (3) predictors selected by stepwise selection also appeared in the top 10 models in all-subsets analysis, (4) there was no evidence that a particular relationship was driven by spatial confoundment, and (5) there was an obvious mechanistic explanation for strength and direction of an observed statistical relationship.

Note that we also conducted an analysis of potential predictors of zebra mussel abundance (see Sckrabulis, Reference Sckrabulis2020), but this is outside the scope of the current manuscript.