Study area

The study was conducted between November 2019 and May 2020 at the Parque Ambiental Macambira (16°44′26.20″ S, 49°19′11.10” W, 827 m above sea level) in the city of Goiânia, Brazil. The park is used for recreation and educational purposes and lacks large-scale human disturbances, such as mowing, fires, and logging. The park contains a typical and conserved Cerradão with trees up to 10 m tall. The climate has two well-defined seasons: a dry winter from May to September and a rainy summer from October to April.

The park is an urban fragment with approximately 25 ha and is surrounded by avenues and houses all around its borders. The park itself is asymmetric; one part resembles an arrow, and the other a square, both of which are linked by a boomerang-shaped area of vegetation. The so-called west edge (16°44'26.20"S, 49°19'10.64"W) is limited by a matrix formed by deforested land containing a few shrubs and grasses; this matrix extends up to 150 m until the nearest street (Supplementary material 1). The so-called east edge (16°44'23.07"S, 49°19'6.63"W) ends in an avenue. The interior of the park is well preserved with large trees with canopies covering the understory and does not sustain perturbations other than storms that once in a while may provoke the fall of trees and branches. The most frequent plant species are Hymenaea courbaril L. (Fabaceae), Tapirira guianensis Aubl. (Anacardiaceae), Xylopia sericea A. St.-Hil. (Annonaceae), Schefflera morototoni (Aubl.) Maguire, Steyerm. & Frodin (Araliaceae), Mauritia flexuosa L. f. (Arecaceae), and Anadenanthera colubrina (Vell.) Brenan (Fabaceae).

Study plant

The genus Inga is restricted to the neotropics and contains approximately 300 species (Kursar et al. Reference Kursar, Dexter, Lokvam, Pennington, Richardson, Weber, Murakami, Drake, Mcgregor and Coley2009). The study plant, I. laurina, grows up to 20 m tall. The EFNs occur at the base of the opposite leaflets. The leaf flush is related to the onset of the rainy period (October), and the production of extrafloral nectar is continuous throughout the dry season, which lasts until April (end of the rainy season). From May to September, the plant does not produce any leaves, and the EFNs are non-functional. Several species of Inga are known to be visited by EFN-drinking ants, and studies have examined the potential of ants as antiherbivore defences in Inga, as well as the performance of plants in different environments (Koptur Reference Koptur1985, Kersch & Fonseca Reference Kersch and Fonseca2005, Bixenmann et al. Reference Bixenmann, Coley and Kursar2013). Two species of Inga are present in the park (I. alba (Sw.) Willd and I. nobilis Willd.), and together with I. laurina, these legumes are part of the park’s management plan.

Experimental design

We established a study design with 4 rows per 11 column-transects in the park; each row contained 22 plants and each column had eight plants. The largest linear transects were 200 m long (Figure 1) and were set from one edge to the other of the park (Supplementary material 1). A total of 88 seedlings of I. laurina were purchased from a commercial greenhouse located in Goiânia city, Brazil, transported to the park and transplanted into established transects. At this point, the seedlings were between 15 and 20 cm tall, and there was no significant difference in height, number of leaves, and number of EFNs between plants (p > 0.05 in all cases, details not shown here).

Figure 1. Representation of the transects established in the park to grow the individuals of Inga laurina. Each row sustained 22 seedlings, which were assigned as ant-present or ant-excluded treatments. Rows started from the very west edge and ended at the east edge (the limit between the park and the surrounding non-forested matrix). A clear delimitation of the extension of edges and the interior was made later, based on microclimatic data and statistical analyses (see Results section) (see also Supplementary material 1).

Each linear transect was 200 m long and was spaced 10 m from each other. A total of 22 seedlings of I. laurina were planted in pairs (one ant-present and another ant-excluded seedling) in each transect; each pair was 20 m distant from the other pair, and each plant from each pair was 1 m distant from the other (Figure 1).

Our sample size was equal to 88 seedlings (11 plant pairs times 4 transects = 88 seedlings), which were divided into ant-present and ant-excluded individuals (n = 44 plants in each group). The restriction of ant access to plants was made with the use of nontoxic wax (Tanglefoot ©), which was applied to the foot of each ‘ant-excluded’ seedling. The ‘ant-present’ plants were left undisturbed, except by a thin layer of wax which was applied to a portion of the main stem to control for the effect of the wax; this did not restrain the access of ants to plant parts. Leaves and stems from each seedling were clipped to avoid the formation of vegetation bridges between plants.

In many ant-plant studies, scientists tag single individual plants and divide their bushes into experimental units where one bush receives the resin to avoid ants and a neighbour bush is assigned as a control unit (Alves-Silva et al. Reference Alves-Silva, Bächtold, Barônio, Torezan-Silingardi and Del-Claro2014, Aristizábal & Metzger Reference Aristizábal and Metzger2019). The advantage of this approach is that herbivores can rapidly assess the ant-free areas and forage accordingly. In addition, insects that whenever are harassed by ants in control bushes can rapidly fly to the nearest ant-excluded plant parts to keep feeding. In our study, the I. laurina plants were rather small to be divided into experimental bushes, so we preferred to grow two seedlings, one with and the other without ants, close to each other (1-m space), which covers the distance between experimental plant pairs in the study by Mody & Linsenmair (Reference Mody and Linsenmair2004).

We might also have chosen to not distribute the I. laurina in experimental pairs, but rather into ant-present and ant-excluded plants that were distributed evenly in the park and distant from each other. However, we were afraid that some plants might perish, which would affect the even sample size between experimental plants. In our current approach, if one plant from the pair perished, its counterpart was going to be excluded from the study as well; luckily this did not happen. To conclude, the decision to keep plant pairs 1-m spaced from each other was based on a logistic reason, since it permitted a quick evaluation of plants by one researcher in the field.

Data collection

Data collection commenced 21 days after plant acclimation in the area. The plants were scanned six times, from mid-December to late March, which corresponds to the wet season (see results for the dates). Field trips were carried out on December 16 (2019) and in the following dates of 2020: January 6, January 27, February 17, March 9, and March 30. In each field trip, the ‘ant-present’ seedlings were scanned for the presence of ants, and the ant-excluded plants were also checked to guarantee that no ants trespassed the wax barrier. Ants visiting the control plants were photographed to permit an initial classification to the genus level (this is possible for common genera, such as Camponotus, Cephalotes, and Crematogaster) (Supplementary material 1). At the end of the fieldwork, the ants were collected.

Our measure of herbivory was the ratio between the number of leaves and the number of leaves with herbivory (leaf area loss) in each seedling (González-Teuber et al. Reference González-Teuber, Silva Bueno, Heil and Boland2012). First, we aimed to measure herbivory as the leaf area loss (% and mm² per leaf), using digital images. However, leaves usually had most of their areas and margins attacked by beetles and caterpillars, thus restraining us from measuring leaf area loss with accuracy (Supplementary material 1). Our measure of herbivory might not have been the most appropriate (i.e., damaged leaves divided by the total number of leaves; Alves-Silva & Del-Claro Reference Alves-Silva and Del-Claro2014; González-Teuber et al. Reference González-Teuber, Silva Bueno, Heil and Boland2012), but it was the only possible method to assess the herbivory levels in I. laurina. Nonetheless, Burger et al. (Reference Burger, Vondráčková, Skłodowski, Koid, Dent, Wallace and Fayle2021) did not notice differences between this method and the measure of leaf area loss. Thus, we believe our results are trustworthy.

Microclimatic data (temperature, humidity, and sunlight exposure) were collected to permit the classification of the edges and the interior of the fragment, because differences in temperature and humidity, for instance, are strikingly different on the edges and the interior, permitting its recognition and use in statistical analyses (Christianini & Oliveira Reference Christianini and Oliveira2012, Mendonça et al. Reference Mendonça, Russo, Melo and Durigan2015). Temperature and humidity data were recorded in the mornings (08:00 to 09:00 to avoid daily variation; Wang et al. Reference Wang, Lei, Li, Fan, Li, Sun and Chang2009) of sunny days using a digital thermo hygrometer (MTH-1300 Minipa). The device was placed between each pair of seedlings, and the data were recorded. The light incidence was measured with Google’s smartphone app Science Journal for Android OS (V. 3.5.329666436 from 2020; the app was discontinued by Google). By using the app, a single smartphone (model Samsung S9) was consistently used throughout the study, and it was held above and between the pairs of I. laurina. The camera then registered the luminosity in lux units.

Statistical analyses

The microclimatic data (light, temperature, and humidity) were visualized in different figures, and data were not linear, but rather varied depending on the location of the transects (Figure 2a, b, c). For instance, the last group of tagged plants (locate at a distance of 200 m along the transect – Figure 1), located on a border of the park (on the east), had the highest temperature and luminosity, and the lowest humidity. In contrast, some transects in the interior of the fragment had opposite values.

Figure 2. Variation of (a) temperature, (b) humidity, and (c) luminosity along the 200 m long transect within the park. In those places regarded as ‘edges,’ we noticed a visible contrast of environmental factors in comparison to the interior. The figure shows the mean and standard deviation.

A non-linear regression was made for each microclimatic variable, yielding polynomial models for temperature (intercept = 25.24, x = −0.74, x² = 0.08); humidity (intercept = 76.84, x = 4.72, x² = −0.44) and luminosity (intercept = 4930.0, x = −2086, x² = 201.5). We fit an adjusted curve along the fragment’s transects which demonstrated a parabolic trend of temperature, humidity, and luminosity. Regardless of the microclimatic variable, all of them showed that the inner part of the fragment (the interior) had different conditions in comparison with the borders. In fact, the adjusted parabolic curve allowed us to recognize three distinct areas within the fragment, which were labelled as ‘west edge’, ‘interior’, and ‘east edge’ (Figure 2a, b, c). The visual estimation and classification of edges and the interior were appropriate in our study as figures, and the polynomial adjusted regression curves were used to quantify how physical variables varied along the transects.

A more traditional approach would be to pairwise-compare each part of the transect to classify them onto edges and interior; however, this is not feasible due to the characteristics of the fragment. For instance, the temperature in the 20 m and 180 m transects was similar (Figure 2a) and one might assume that both parts of the transect should be put in the same categorical factor; nonetheless, they are 160 m away from each other and are separated by parts with lower temperatures. The 180 m transect is also very different (in terms of temperature, humidity and luminosity) from the subsequent transect (200 m) (Figure 2a). The adjusted parabolic curve revealed that the edges had increased values of temperature and light in comparison to the interior; in contrast, the humidity was conceivably lower on the edges. According to our classification, the west edge accounted for two transects (0 to 20 m, n = 16 plants), the interior for eight transects (40 to 180 m, n = 64 plants) and the east edge for one transect (200 m, n = 8 plants) (Figure 2a, b, c).

In order to statistically compare the microclimatic data among these three habitat types indicated by Figure 2, we performed Kruskal–Wallis test (non-parametric data) followed by Dunn’s test (a posteriori) for the values of temperature, humidity and sunlight exposure in each habitat type. Once we realized that the physical data of these three sites were statistically different (see Results section), the west edge, the east edge, and the interior of the fragment were incorporated into the subsequent analyses as categorical data.

General linear mixed model tests (GLMM) were used to examine the influence of plant groups (with or without ants), the location of plants in the transects, and dates of sampling (employed as a fixed and also as the random factor) on herbivory (% of attacked leaves per plant). Tukey’s post hoc tests were made whenever necessary to investigate in detail results that were statistically significant.

To verify if the herbivory data were spatially correlated, which might influence the results, we made Moran’s and Mantel tests, as well as a linear mixed-effects regression with spatial data of plants. None of the analyses were significant (results not shown); thus, we rule out the spatial location of plants as a variable of influence in our study.

Statistical procedures were performed using R statistical software, version 4.2.2.