Framework overview

Our framework (Fig. 1) begins with conservation-zone delineation. This process could be subjective (e.g., based on neighbourhood boundaries or input from local planners) or could identify environments based on attributes such as land cover using techniques such as k-means (MacQueen Reference MacQueen1967), hierarchical (Rokach & Maimon Reference Rokach, Maimon, Maimon and Rokach2005) or spatially constrained multivariate (Duque et al. Reference Duque, Ramos and Suriñach2007) clustering. Clustering approaches could delineate zones that better represent environmental conditions while subjective approaches could produce zones that are easier to administer in practice. Approach selection should be based on social–ecological conditions or conservation programme objectives. The resulting conservation zones should reflect particular habitat conditions and will be the focus of tailored management efforts focused on local conservation objectives.

Fig. 1. Flowchart that depicts the five framework steps, their goals and the steps used in their implementation in the case study example.

Our second framework step identifies indicator communities for each zone while our third framework step identifies their habitat requirements. Indicator communities are multi-species conservation surrogates that consist of species with close links to zones whose habitat requirements indicate zone attributes that affect their biotic communities. Conservation surrogates are often required when time and funding limitations constrain projects (Caro et al. Reference Caro, Girling and Girling2010), and different surrogates are typically needed for different conservation zones (Goddard et al. Reference Goddard, Dougill and Benton2010). We suggest that indicator communities, rather than single indicator species, may better represent broader communities and support their conservation (Roberge & Angelstam Reference Roberge and Angelstam2004). The focus of these communities (e.g., taxonomic, rare species, common species) should reflect conservation programme objectives and should be selected in collaboration with local experts and stakeholders to ensure their fit with those objectives. As noted above, human-maintained species such as garden plants and pest species against which humans mount active control measures should be avoided in constructing indicator communities as their abundance may reflect human management more than local habitat conditions.

Indicator-community development uses georeferenced, species abundance data for a taxon or multiple taxa, depending on conservation goals. Data could be collected by experts or citizen-scientists via field surveys or from existing sources (e.g., Sullivan et al. Reference Sullivan, Aycrigg, Barry, Bonney, Bruns and Cooper2014). Observations are classified by zone, and species closely associated with a zone are identified using indicator-community analysis (e.g., Dufrêne & Legendre Reference Dufrêne and Legendre1997) and comprise its indicator community. Community abundance or richness modelling techniques are then employed to assess each indicator community’s relationships with habitat attributes. Coefficients for covariates from these models identify key habitat attributes and relationships for each management in a conservation zone.

Our fourth framework step identifies human habitat preferences within conservation zones. Surveys, participatory mapping or focus groups could be used to identify preferences for the habitat attributes used in indicator-community habitat modelling. Preference assessment could also use revealed-preference economic valuation techniques (e.g., contingent valuation, hedonic pricing) that identify habitat preferences based on surveys or the values of marketed goods to which they contribute (Freeman Reference Freeman2003).

The final framework step identifies similarities and differences between indicator-community and human habitat preferences by comparing human and indicator-community habitat preferences by conservation zone. Attributes with similar relationships for humans and indicator communities could be managed to support both species conservation and human well-being in each zone. Management of attributes with different relationships could cause conflict. Management should avoid these attributes if possible or proactively address potential conflict prior to implementation. Conservation zones and their identified human and species habitat relationships could thus provide preliminary data to guide conservation planning activities including stakeholder discussions and management plan development, providing a foundation for conservation planning.

Case study

We demonstrate our framework in Iowa City, a city of 75,000 residents, which consists predominantly of suburban environments over an area of 65 km² (US Census 2018) and includes grass (43%), impervious (27%), forest (17%), agriculture (10%) and water and wetland (3%) cover. Most wetland and contiguous forest cover occurs in parks. Surrounding landscapes consist largely of corn and soybean agriculture (IDNR 2012). Iowa City encourages urban infill and most new construction within the city occurs on urban renewal sites and agricultural land (City of Iowa City, 2013), while most development in the surrounding area occurs on agricultural land (Johnson County, 2020). We identified conservation zones, human habitat preferences and indicator communities and their habitat requirements for this study area to illustrate our framework (Fig. 1).

In the first step in our framework, we used k-means clustering to identify conservation zones (Fig. 1a). This process began by overlaying a 50-m grid on the study area, then identifying proportional built (e.g., pavement, buildings), canopy and grass cover in each grid cell using 1-m resolution 2009 High-Resolution Land Cover (HRLC; IDNR 2012) updated to represent development since 2009 (see Zhao & Sander Reference Zhao and Sander2018) and a lidar-derived urban forest dataset (Zhao & Sander Reference Zhao and Sander2018) in ArcGIS v10.6 (ESRI 2018). We then used the resulting dataset to implement k-means clustering in the R v3.4.1 (‘Single Candle’) package stats (R Core Team 2017) to delineate different conservation zone classification schemes for our study area based on proportional built, canopy and grass cover in each 50-m grid cell. We constructed and examined a series of classification schemes that grouped grid cells into 4–12 zones and selected the scheme that produced conservation zones that were neither too general (i.e., covering large areas of heterogeneous landscapes) nor too specific (i.e., covering small, fragmented areas or including very few grid cells); in this case, this meant selecting a scheme that included five zones. Each grid cell in our 50-m grid was thus classified into one of five conservation zones.

In our second framework step (Fig. 1b), we used point-count data to construct songbird indicator communities for conservation zones. Using stratified random sampling, we selected 259 survey plots (hereafter, ‘plots’) to represent the proportional occurrence of each conservation zone type in the study area. To do so, we used conservation zones as strata and sampled a number of grid cells proportionate to the occurrence of each zone type in the landscape. We used the centroid of each selected grid cell as the centre of a 50-m radius survey plot. Two experienced birders conducted 10-min point-count surveys (Reynolds et al. Reference Reynolds, Scott and Nussbaum1980) on these plots from June to mid-July (the peak breeding season in eastern Iowa) during 2014–2016 on dry days without strong winds within 4 h of sunrise (Bibby et al. Reference Bibby, Burgess, Hill and Mustoe2000), visiting each plot four times in total (Sander & McCurdy Reference Sander and McCurdy2021). Half of these plots were visited twice in 2014 and twice in 2015, 40% were visited twice in 2015 and twice in 2016 and 10% were visited once in 2014 and three times in 2015 due to flooding that restricted access to these plots in late June and early July of 2014.

We next constructed binomial N-mixture models – hierarchical models that use repeated counts to predict true abundance adjusting for imperfect detection probability (Kéry et al. Reference Kéry, Royle and Schmid2005) using the R package unmarked (Fiske & Chandler Reference Fiske and Chandler2011) for species detected on 5% or more of plots given the lower effectiveness of this approach for less commonly detected species. Excluding these species assumes that the conservation of more common species is the focus of this application; in cases where conservation targets rarer species, alternative modelling approaches such as multispecies beta N-mixture modelling (Gomez et al. Reference Gomez, Robinson, Blackburn and Ponciano2018) or approaches that use rarefaction could be employed. These models include detection (i.e., likelihood of observing a species that is present) and abundance (i.e., true abundance given imperfect detection) sub-models. We included minutes since sunrise, plot forest cover from the HRLC and categorical covariates for survey year and surveyor in our detection sub-model and agricultural, grass and built cover from the HRLC and canopy cover from an urban forest dataset as abundance covariates (Supplementary Table S1, available online). We first fitted detection models with all abundance covariates using all combinations of detection covariates and Poisson distributions and selected the best-fitting model based on the minimum Akaike information criterion (AIC), then we fit abundance sub-models in the same manner. We refitted top models with zero-inflated Poisson and negative-binomial distributions, selecting models that minimized AIC, and calculated goodness-of-fit statistics following MacKenzie and Bailey (Reference MacKenzie and Bailey2004). We assessed residual spatial autocorrelation for each model using Moran’s I statistic and, when results were significant, calculated spatial autocovariates in the R package spdep (Bivand & Yu Reference Bivand and Yu2022) using the autocov_dist function and added them to the top models to address this autocorrelation. We used the resulting models to predict the true abundance of each species on each plot, then we used the multipatt function of the R package indicspecies (De Cáceres & Legendre Reference De Cáceres and Legendre2009) to implement Dufrêne–Legendre indicator species analysis to identify species with significant, positive relationships between abundance and each conservation zone. These species comprised the indicator community for that zone.

In our next framework step, we modelled relationships between indicator-community species richness and habitat attributes to identify indicator-community habitat attributes (Fig. 1c). We first pooled counts of species in each indicator community to create indicator-community richness datasets for each visit to each plot. We calculated habitat covariates for plots and 250-m radius areas surrounding them (hereafter, ‘neighbourhoods’) from the above datasets (Table S1) in ArcGIS to identify habitat attributes on and surrounding each plot including built, agricultural, grass, wetland and water cover; mean canopy cover and tree height; and vertical structure and tree height standard deviation (Table S1). We calculated attributes at both local (plot) and neighbourhood (250-m) levels given that birds respond to their environments at local and landscape levels in choosing breeding sites (Pennington & Blair Reference Pennington and Blair2011, Rega-Brodsky & Nilon Reference Rega-Brodsky and Nilon2017), suggesting that habitat management should focus on both extents. Other applications of this approach could include variables measured over either one or both of these extents to match with the extents over which conservation actions will be targeted. Lastly, to measure landscape structure on and surrounding each plot, we calculated landscape metrics, including the patch cohesion index (a metric that identifies the degree to which patches of the same land-cover type are aggregated such that values of 0 indicate isolation while increasing values indicate increasing aggregation; i.e., spatial connectivity) to indicate forest, built and grass connectivity and Simpson’s diversity index to identify land-cover heterogeneity using Fragstats v4 (McGarigal et al. Reference McGarigal, Cushman and Ene2012) and the HRLC. We used this dataset and the detection covariates employed in species abundance modelling to construct binomial N-mixture models in order to identify the relationships between the species richness of each indicator community (i.e., count of species observed on a site) and mean-centred and scaled habitat covariates using the process outlined above. We used coefficients for habitat covariates from the final richness models for each indicator community to identify habitat relationships for its conservation zone.

In our next framework step, we identified human habitat preferences using a local hedonic pricing model (HPM), an economic valuation technique that can utilize readily available tax-assessor data (Fig. 1d). HPM is a statistical modelling approach under which the sale price, P, of a marketed good (e.g., residential parcel), i, is seen as a function of its structural (S _i ), neighbourhood (N _i ) and environmental (habitat) attributes (Q _i ; Freeman Reference Freeman2003), such that:

(1) ${P_i} = {\beta _0} + {\beta _1}{S_i} + {\beta _2}{N_i} + {\beta _3}{Q_i} + {\varepsilon _i}$

Estimated coefficients identify the direction and magnitude of the relationships between parcel price and covariates, and, under assumptions that the geographical area in question represents a single, perfectly competitive market in equilibrium and that buyers are well-informed, the covariates also identify how much homeowners are willing to pay for those attributes (Freeman Reference Freeman2003), thereby indicating homeowner preferences for those attributes, including preferences for habitat attributes. While HPMs typically use global regression, fitting one regression equation for a study area with one coefficient for each covariate, they can be implemented using a local regression technique, such as geographically weighted regression (GWR). GWR can capture variation in homeowner preferences by estimating coefficients for each covariate for each parcel in a sample, such that:

(2) $${P_{ij}} = {\rm{ }}{\beta _{j0}} + {\beta _1}{S_{ij}} + {\beta _2}{N_{ij}} + {\beta _3}{Q_{ij}} + {\rm{ }}{\varepsilon _{ij}}$$

where j represents specific parcels (Fotheringham et al. Reference Fotheringham, Brunsdon and Charlton2002). We used GWR to estimate HPMs using the attributes of 2316 single-family residences and the land (i.e., cadastral parcel) associated with them (hereafter, ‘parcels’) that sold in the area during 2011–2015 identified from data from the Iowa City Tax Assessor. The single-family parcels used in this case study occurred solely in existing residential areas (i.e., they were not in newly developed locations) within the City of Iowa City’s municipal boundary, which is in alignment with the intent of the framework to support conservation in existing urbanized settings and not to identify or plan building in undeveloped locations. In implementing GWR, we used the natural logarithm of the sale price in 2015 US$ as our dependent variable and included structural covariates from tax-assessor data (lot area in acres; building and garage area in ft²; numbers of rooms, bathrooms and fireplaces; age in years; presence of air conditioning; location in a flood zone) and binary covariates for the presences of a neighbourhood elementary school to indicate neighbourhood attributes. We calculated habitat covariates for parcels (all land within the ownership boundary for each parcel) and surrounding neighbourhoods (Table S1) as described above for bird modelling. We utilized a spatially adaptive kernel and followed a cross-validation approach that used predicted values to minimize the residual sum of squares and an adaptive bandwidth of c. 85 neighbours in implementing GWR. We identified parcels with significant relationships between each covariate and sale price in each zone, then we calculated the mean coefficient for that covariate for those parcels and used the resulting values to identify human habitat preferences in each zone.

In our last framework step, we compared mean coefficients for each zone with indicator-community habitat relationships to identify commonalities and differences in the habitat preferences of humans and indicator communities within conservation zones (Fig. 1e).