Sampling Methods.

We conducted bat surveys in 30 of the 40 experimental plots (Figure 1) at the onset of restoration, between May and December 2018. All 30 sites were sampled twice unless otherwise noted. The remaining ten plots were not surveyed due to logistical constraints (timeframe, personnel), and because the 30 plots that were sampled sufficiently represented the different planting strategies at the time of the study. Thirteen of these 30 plots were planted one year prior to sampling (hereafter referred to as planted sites), seven were planted in the year of sampling (immediately before or immediately after surveys, hereafter referred to as not planted sites), and ten were natural regeneration plots (Online Appendix 1, Figure 1.1). To provide the necessary context for the initial (baseline) community composition in areas to be restored, we also conducted bat surveys at 14 sites in the surrounding forested area, which included old growth and secondary forest in close proximity. We ensured that one of the two sampling rounds at each site took place in little to no moon visibility, since bat activity decreases in moonlit conditions (Saldaña-Vázquez & Munguía-Rosas, 2013).

Capture Surveys.

In order to sample bats in the family Phyllostomidae, which includes all frugivorous (i.e., seed dispersers), nectivorous (i.e., pollinators) and gleaning animalivore species, we conducted mist-net surveys, which remains the most effective method for monitoring members of this family (Avila-Cabadilla et al., 2012). In the restoration sites, we set-up mist nets at the center of the 0.5-ha plot in a modified ‘H’ configuration, using two 12 × 2.5 m nets and one 9 × 5 m net (105 m² of mist-net per night, unless otherwise noted and accounted for in sampling effort; Online Appendix 1, Figure 1.1). In the forest sites, we used existing trails and clearings to block bat flyways: the area of mist-nets used at forest sites ranged from 75 m² to 105 m², depending on available space. Mist-nets were raised at sunset (between 17:45 and 18:00) and remained open for four hours. We interrupted netting during heavy rainfall. Once nets were open, we checked them for bats every 10 to 15 minutes. Once bats were removed from the net, they were kept in cloth holding bags until the end of the survey, to avoid recaptures. Bats were identified in the field, according to F. A. Reid (2009) and nomenclature followed York et al. (2019). Because of the difficulty of differentiating Dermanura watsoni and D. phaeotis based on dental characteristics, we identified captured individuals as D. watsoni, because of their greater likelihood of occurrence in the study region (F. A. Reid, 2009).

Acoustic Surveys.

Acoustic sampling is most effective for the detection of aerial insectivores because most produce louder echolocation calls than phyllostomid species, but unlike the latter are less likely to be captured in mist-nets (Meyer et al., 2011). At the time of netting, we simultaneously recorded echolocation calls at the center of netting sites using full spectrum SM4bat detectors (Wildlife Acoustics, Maynard, MA, USA) placed ∼ 1.5 m above ground. Calls were automatically recorded for one minute (recording interval) every 10 minutes for four hours at a sampling rate of 256 kHz, with trigger levels set at 16 kHz and 12 dB.

For species identification, spectrograms from the recordings were reviewed on screen by experienced observers (D. A. and E. H. A.) following the procedure described in Estrada-Villegas et al. (2010). The spectrograms were produced with either Kaleidoscope (v. 4.2.0) or SongScope software (v. 4.0, Wildlife Acoustics), selecting an FFT size of 256 and a 128 window size. Search phase calls were compared to a compilation of published call characteristics for species that are known to occur in the area and documented in a call library for the study site (see Online Appendix 2 for call identification criteria and sources).

Bat Communities in Restoration and Forest Habitats.

Given the different sampling methods, all analyses were conducted separately for phyllostomids (capture data) and aerial insectivores (acoustic sampling). The analysis of capture data excluded all non-phyllostomid bats (5% of bat captures, by individual). We conducted all analyses in R (v. 3.6.1) using RStudio (v. 1.2.1335; R Core Team, 2019; RStudio Team, 2018), and graphically depicted results using the package ggplot2 (Wickham, 2016) and in SigmaPlot (v. 13). We quantified species richness for each of the two surveys at every sampling site. For each species or identified taxonomic unit (see Online Appendix 2), we also calculated a detection rate for each night of sampling. For phyllostomids, this was the capture rate per night (individuals/hr). For aerial insectivores, this was an activity index equal to the number of one-minute sampling intervals during which the species was detected per night. Such indices of activity based on occurrence counts are used as a proxy for abundance across habitat types and to compare the composition of aerial insectivore assemblages (Estrada-Villegas et al., 2010, 2012; Heer et al., 2015).

We assessed differences in species diversity across habitat types by calculating and plotting sample-size-based rarefaction and extrapolation (R/E) curves for Hill numbers using the package iNEXT (Hsieh et al., 2016). Species observations were pooled for the two sampling sessions and ‘sites’ were used as sampling units. We used species incidence (presence/absence) to calculate three Hill numbers—species richness, Shannon diversity, and Simpson diversity—with the function iNEXT, using the “incidence_raw” datatype. We plotted estimated values, sample coverage, and rarefied estimates, and assessed the overlap of the 95% confidence intervals to assign significance of differences in species diversity across habitat types (Chao et al., 2014).

To detect differences in capture/detection rate of phyllostomids and aerial insectivores between forest and restoration habitats, we used mixed effects models using the package lme4 (Bates et al., 2015). We modelled phyllostomid capture rate (individuals/hr; log transformed) and aerial insectivore detection rate (ratio of the number of sampling intervals in which each species was detected in a night, summed across detected species; log transformed) using mixed-effect linear models, with sampling site as a random effect. Because bat activity can be affected by moonlight (Saldaña-Vázquez & Munguía-Rosas, 2013), we also included the percent luminosity during the sampling period as an explanatory factor in analyses. Luminosity data was obtained from timeanddate.com (Thorsen, 2019); if the moon was not visible at the time of sampling (i.e., not risen), percent luminosity was set to zero.

Prior to analyzing differences in community composition across habitat types, we conducted a Mantel test on the species-site dissimilarity matrices for each of the four assemblage-habitat combinations and found no spatial autocorrelation in patterns of community composition; dissimilarity matrices were calculated using the function vegdist in the R package vegan (Oksanen et al., 2019), and Mantel tests were conducted using the vegan function mantel (phyllostomid-forest: r = .02, p = .38; phyllostomid-restoration: r = .12, p = .11; aerial insectivore-forest: r = .20, p = .09; aerial insectivore-restoration: r = .07, p = .12). We then took a three-parted approach to explore differences in community composition across habitat types and identified species’ trophic groups to explore emergent patterns across ecological roles of bats. Phyllostomid species were assigned to the following foraging groups, based on the primary component of their diet (F. A. Reid, 2009): frugivore, nectarivore, animalivore, and sanguivore (see Online Appendix 3, Table 3.1). Aerial insectivores were assigned to the following foraging groups: open-space foragers and forest/edge foragers (Online Appendix 3, Table 3.2), based on functional traits and habitat use (Estrada-Villegas et al., 2010; Heer et al., 2015; Jung et al., 2007). First, to describe and visually compare the characteristics of the bat assemblages (species composition and relative abundance) across habitats, we plotted rank abundance graphs (Feinsinger, 2001). We used the proportion of individuals (p_i) captured (phyllostomids) or proportion of detections (aerial insectivores) of a given species relative to the total captures/detections, plotted on a logarithmic scale to facilitate comparisons between plots with different sample sizes. Second, to quantify differences in community composition, we used permutational multivariate analysis of variance (PerMANOVA) using the adonis function in the R package vegan (Oksanen et al., 2019), to determine whether habitat type affected the community composition of phyllostomid and aerial insectivore assemblages. We visualized patterns of community composition using non-metric multidimensional scaling (NMDS), using Bray-Curtis distances, using the vegan function metaMDS (Oksanen et al., 2019). To construct the phyllostomid species matrix, we combined species incidences over the two sampling nights at each site and used the total number of individuals of each species detected at a site as an index of abundance. There was one restoration site at which we did not capture any phyllostomids in either sampling night, thus it was omitted from analysis. To construct the aerial insectivore species matrix, we used the combined species presence/absence over each of the sampling nights at a site. There were two forest sites at which no aerial insectivores were detected in either of the two sampling nights, thus they were omitted from analysis. Third, to quantify habitat type associations across species and trophic groups, we calculated the group-equalized phi correlation coefficient between species’ incidence (presence/absence) and habitat type and the associated 95% confidence intervals using the function strassoc in the R package indicspecies (De Cáceres & Legendre, 2009). Associated p-values were calculated using the function multipatt.

Effect of Landscape Characteristics on Detection Rate in Restoration Habitat.

To evaluate potential landscape correlates of bat abundance in restoration habitat, we modelled the effect of landscape characteristics and early differences in habitat structure due to restoration treatment on phyllostomid and aerial insectivore detection rate. We included the following landscape characteristics: the distance to the forest edge (from the center of each restoration plot to the nearest forest edge, measured in the field), the distance to streams (from the center of each restoration plot, extracted using GIS software), the amount of forest coverage within 200 m of the sampling location, and the presence of vegetation islands (identified in the field as vegetation clusters containing more than three trees). We included the percent forest cover within 200 m of sampling sites as a predictor variable to account for the heterogeneity of forest coverage surrounding each restoration category. We set our buffer size to 200 m based on previous findings from J. L. Reid et al. (2015) that demonstrated that forest structure had the greatest impact on fruit bat activity at this scale. At our study site, this scale is appropriate to reflect between-site variation in nearby forest cover (see Figure 1) while minimizing excessive overlap between sampling points. Percent forest cover within the buffer zone was calculated from aerial imagery in QGIS (v. 3.4; QGIS Development Team, 2019). Because we were only interested in small-scale landscape characteristics, we combined the detection data from the two sampling nights at each restoration site. None of the continuous predictors were strongly correlated, and there were no differences in the mean values of the continuous predictors across restoration treatments, as determined using Kruskal-Wallis tests (Online Appendix 5; Figure 5.1), thus they were all included in the models. We modelled the responses without the intercept, to assess the effect size of each predictor on detection rate. For each sampling technique, we first ran models for the entire assemblage. For phyllostomid capture rate (individuals/hr), we used a linear model; we omitted one outlier to meet model assumptions (see Online Appendix 5, Table 5.1 for details). For aerial insectivore detection rate (activity index) we ran a Gamma generalized linear model (GLM) with a log-link function. To investigate the effect of landscape characteristics on different trophic groups, we then conducted the same analysis on each trophic group separately. Trophic groups with few species and/or detections, which included nectarivores, animalivores, and sanguivores, were modelled using logistic regression (binomial GLM). Frugivores were modelled using a linear model, and forest foragers were modelled with a linear model after detection rate was square root transformed. Open space foragers were modelled using a Gamma GLM with a log-link function.

Bat Communities in Restoration and Forest Habitats.

In the restoration habitat, we captured 18 species of phyllostomid bats, including 10 frugivores, 5 gleaning animalivores, 1 nectarivore and 1 sanguivore (Online Appendix 3, Table 3.1), whereas in the forest habitat, we captured 19 phyllostomid species, including 9 frugivores, 6 gleaning animalivores, 3 nectarivores and 1 sanguivore. The completeness of the inventory, estimated from the rarefaction, was 97% in restoration and 96% in forest (Online Appendix 4, Figure 4.1a). Based on the 95% confidence intervals of the estimated species richness, Shannon diversity and Simpson diversity indices, there were no significant differences between estimated richness, entropy, and evenness between restoration and forest habitat types, although the mean estimates were lower in restoration than in forest habitats (Figure 2A and B). Based on the linear mixed effect model, capture rate was significantly lower in restoration habitat than forest habitat, and luminosity had a small but significant negative effect on capture rate (Table 1).

Figure 2.

Rarefied Diversity Estimates. Estimated species richness, Shannon diversity and Simpson diversity indices with 95% confidence intervals in forest and restoration habitats for (A and B) phyllostomids and (C and D) aerial insectivores. Top panels depict estimated values accumulated by sampling units (sites) and bottom panels depict estimates corrected for sample coverage (survey completeness).

Table 1.

Effect of Habitat Type and Luminosity on Bat Detection Rates.

For aerial insectivores, we detected 14 species in restoration sites, 10 of which were also present in forest sites (Online Appendix 3, Table 3.2). The completeness of the inventory was 100% in restoration habitat and 97% in forest habitat (Online Appendix 4, Figure 4.1b). While there was no significant difference between habitat types on estimated species richness based on overlapping 95% confidence intervals, entropy and evenness, as calculated using the Shannon and Simpson diversity indices, were lower in forest than in restoration habitat (Figure 2C and D). Further, the detection rate of aerial insectivores was significantly lower in forest than in restoration habitat, but there was no effect of luminosity (Table 1).

For phyllostomid community composition, both habitats presented similar shapes of the rank abundance graphs (Figure 3), but the occurrence and relative abundance of species varied between habitats. Some species were only detected in one of the two habitat types, with four species unique to the forest habitat (Chrotopterus auritus, Lophostoma silvicolum, L. brasiliense, and Lichonycteris obscura), and three unique to the restoration habitat (Micronycteris hirsuta, M. minuta, and Chiroderma villosum). In their overall abundance, frugivores represented 77% of all captures in restoration habitat and 85% of forest captures, while nectarivores’ relative abundance was 12% in restoration and 6% in forest. Gleaning animalivores represented 8% and 7% of captures in restoration and forest habitats, respectively. The relative abundance of the only sanguivore, Desmodus rotundus, was similar in both habitat types (2.6% of captures in restoration and 2.3% of captures in forest). Phyllostomid community composition was significantly affected by habitat type (restoration vs forest), based on PerMANOVA (R²= 0.14, p = .001; Figure 4A). At the species level, there were two species that showed a significant association with restoration sites, both frugivores: Uroderma convexum and Sturnira parvidens (Figure 5A). There were three species that showed a significant association with forest sites, also frugivores: Dermanura watsoni, Carollia sowelli, and Artibeus jamaicensis (Figure 5A).

Figure 3.

Rank-abundance Curves of Bat Species by Habitat. Phyllostomid species captured in (A) forest and (B) restoration sites and aerial insectivores detected acoustically in (C) forest and (D) restoration. Labels adjacent to data points represent species ID (list of codes can be found in Online Appendix 3).

Figure 4.

Bat Assemblages Across Restoration (Triangles) and Forest (Circles) Habitats. Ellipses represent the 95% CI of site scores (black = restoration, gray = forest). A: Ordination plot of the phyllostomid assemblage (k = 3, stress= 0.14), with species scores represented by species codes (see Online Appendix 3 for definitions). Species’ trophic groups are denoted by colour: Frugivores in purple, nectarivores in magenta, animalivores in blue, and sanguivores in yellow. B: Ordination plots of aerial insectivore assemblages (k = 3, stress= 0.15) with open-space foragers represented in yellow and forest/edge foragers in orange.

Figure 5.

Habitat Associations by Species. Species selection coefficient for forest habitat (with 95% bootstrapped confidence intervals) for (A) phyllostomids and (B) aerial insectivores. The strength of selection was measured using the group-equalized phi correlation coefficient. Positive values indicate an association with forest, and negative values indicate association with restoration habitat. Species codes are defined in Online Appendix 3. Colors depict trophic group. Significance at alpha = 0.1*, alpha = 0.05**, alpha = 0.01*** calculated by permutation tests.

Acoustic detections were dominated by two species in restoration sites: Saccopteryx bilineata representing 39% of all detections and Molossus sp with 37%: both were detected at all sites. In forest, S. bilineata was the single dominant species representing 56% of all detections and recorded at 11 of the 14 sites. The 11 species classified as forest foragers also occurred in restoration sites (Figure 3C and D). Two of them, Pteronotus personatus and P. gymnonotus were commonly encountered in restoration sites, but were acoustically undetected in forests. In contrast, of the three species classified as open-space foragers, only Molossus sp was detected in forest (10% of detections in that habitat). For the aerial insectivore community composition, the PerMANOVA also revealed a significant effect of habitat type (R²= 0.22, p = .001; Figure 4B). At the species level, five species displayed a significant association with restoration sites: only one was an open space forager (Molossus sp), and the remaining four were forest species (Pteronotus personatus, Myotis albescens, P. gymnonotus, and Saccopteryx bilineata; Figure 5B). Two species displayed a significant association with forest sites, both forest foragers (Centronycteris centralis and Myotis riparius; Figure 5B).

Effect of Landscape Characteristics on Detection Rate in Restoration Habitat.

Among the 30 restoration sites, 10 were natural regeneration, 13 had been planted within the last 1.5 years, and 7 had not yet been planted or had been planted no more than four months prior to sampling. Of the 30 sites, only 10 had vegetation islands. The mean distance to the forest edge was 61.38 m (±29.91 m s.d.) and ranged from 22.1 m to 130 m. The mean distance to the nearest stream was 100.24 m (±31.42 m s.d.) and ranged from 49.08 m to 160.38 m. The mean percent forest cover within 200 m of the site was 25% (±21% s.d.), and ranged from 0% to 71%. Phyllostomid capture rate was significantly higher in natural regeneration sites and in sites with at least one vegetation island (Figure 6; Table 2). Frugivore capture rate was also significantly higher in sites with at least one vegetation island, while nectarivore presence was significantly positively affected by percentage of forest coverage (Table 2). The presence of animalivores and sanguivores was not significantly affected by any of the landscape characteristics (Table 2). The combined detection rate of aerial insectivores was also not significantly affected by any landscape characteristics (Figure 6). However, both forest foragers and open space foragers were independently affected by the restoration treatment; detection rate was highest in natural regeneration sites for forest foragers, but was highest in the planted sites for open space foragers (Figure 6; Table 2).

Figure 6.

Detection Rates in Restoration Habitat by Treatment Category. (A) Phyllostomid detection rate (individuals/hr) and (B) aerial insectivore detection rate (activity index). The left-most panel depicts detection rate of the entire assemblage, and subsequent panels depict detection by trophic group.

Table 2.

Effect of Landscape Characteristics And Restoration Treatment On Bat Detection Rate Or Presence/Absence In Restoration Habitat.