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Phenotypic plasticity and insect herbivory of trees in contrasting light environments in a Mexican rainforest

Published online by Cambridge University Press:  20 November 2024

Daniel A. Cadena-Zamudio Open the ORCID record for Daniel A. Cadena-Zamudio [Opens in a new window] ,
Roger Guevara  and
Betsabé Ruiz-Guerra
Daniel A. Cadena-Zamudio*
Affiliation:
Red de Biología Evolutiva, Instituto de Ecología A.C, Xalapa, Veracruz, México
Roger Guevara
Affiliation:
Red de Biología Evolutiva, Instituto de Ecología A.C, Xalapa, Veracruz, México
Betsabé Ruiz-Guerra
Affiliation:
Red de Interacciones Multitróficas, Instituto de Ecología A.C, Xalapa, Veracruz, México
*
Corresponding author: Daniel A. Cadena-Zamudio; Email: [email protected]
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Abstract

Contrasting light environments in rainforests generates changes in the characteristics of the leaves and in the herbivore community. In the present study, we carried out a reciprocal transplant experiment under natural conditions to determine the plasticity of leaf characteristics of plant species that grow in contrasting light environments in a Neotropical forest. We further explored the relationship between these traits and insect herbivory. We found that six woody species differ markedly in the phenotypic plasticity of leaf features. The specific leaf area, chlorophyll content, carbon content, nitrogen content, and leaf thickness of the most light-demanding species were highest in gaps, but their carbon/nitrogen ratios were higher under closed canopies. The herbivores were more abundant in gaps (5.9%–14.8%) than under closed canopy habitats (3.4%–6.1%) and seemingly associated to the plasticity of the leaf traits. We observed 47% more herbivores in gaps than under closed canopies. Our results suggest that the phenotypic plasticity of leaf traits depends on the identity of the plant species and its wood density, while herbivory seems to be affected by plant defence, low nutritional quality, or herbivore tolerance.

Keywords

Functional plant traitsinsect herbivoryLos TuxtlasNeotropical rainforestplant–herbivore interaction
Type
Research Article
Information
Journal of Tropical Ecology , Volume 40 , 2024 , e25
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Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

In tropical ecosystems, light reaching the understory ranges between 1% and 3% of the total photon flux density available in the upper canopy layer (Dupuy and Chazdon Reference Dupuy and Chazdon2008). Photosynthetically active radiation varies by three orders of magnitude from closed canopy understory to gaps (Stiegel et al. Reference Stiegel, Entling and Mantilla-Contreras2017). Therefore, light is considered a limiting resource that influences understory plant growth, reproduction, and survival (Baraza et al. Reference Baraza, Zamora and Hódar2010). Gaps produced by the fall of large branches and tall trees are an important component of forest regeneration dynamics, and it is estimated that the average hectare of tropical forest has up to eight gaps smaller than 100 m2 (Poorter et al. Reference Poorter, Amissah, Bongers, Hordijk, Kok, Laurance and van der Sande2023). One of the most notable changes in gaps compared to the closed forest canopy is greater light availability, so understory plants and those thriving in gaps must continually adjust to a changing light environment by modifying the expression of physiological, anatomical, and morphological traits (Lundgren and Des Marais Reference Lundgren and Des Marais2020; Laughlin Reference Laughlin2023).

Changes in leaf traits allow plants to adapt to light heterogeneity efficiently (Valladares et al. Reference Valladares, Wright, Lasso, Kitajima and Pearcy2000). For example, light-demanding species allocate resources to rapid growth, allowing them to escape the shade of the understory by growing taller to reach areas where light is more abundant. They are characterised by thin leaves with high nitrogen content and more chloroplasts, which allow higher photosynthetic yield, keeping their leaves cool despite being exposed to intense solar radiation (Poorter and Bongers Reference Poorter and Bongers2006; Tripathi et al. Reference Tripathi, Bhadouria, Srivastava, Devi, Chaturvedi and Raghubanshi2020). In contrast, shade-tolerant species generally have thick, nitrogen-deficient but carbon-rich leaves and a low photosynthetic rate despite their high levels of chlorophyll (Falster et al. Reference Falster, Duursma and FitzJohn2018). In turn, these characteristics determine herbivory levels; for example, light-demanding leaves are consumed by insects more frequently than shade-tolerant leaves (Gianoli et al. Reference Gianoli, Salgado-Luarte and Escobedo2023).

Phenotypic plasticity is the ability of an organism to express different phenotypes in response to its biotic or abiotic environment (DeWitt and Scheiner Reference DeWitt, Scheiner, DeWitt and Samuel2004; Adler et al. Reference Adler, Salguero-Gómez, Compagnoni, Hsu, Ray-Mukherjee, Mbeau-Ache and Franco2014; Adams et al. Reference Adams, Stewart, Polutchko, Cohu, Muller and Demmig-Adams2023). Many plants are phenotypically plastic and can respond to environmental cues in a variety of ways, including changes in their biochemical, physiological, and morphological traits (Agrawal Reference Agrawal2001). Also, phenotypic plasticity can differ depending on the species and their leaf traits. For example, light-demanding species are characterised by having greater plasticity in physiological traits than in morphological traits (Valladares Reference Valladares2003). Phenotypic plasticity is thought to be greater in light-demanding species because they grow in a more variable environment with abundant resources (Scheepens et al. Reference Scheepens, Deng and Bossdorf2018). For example, Lortie and Aarssen (Reference Lortie and Aarssen1996) mention that specialisation in favourable environments increases plasticity, whereas specialisation in less desirable environments decreases plasticity. This evidence suggests that light-demanding species should exhibit greater phenotypic plasticity than shade-tolerant species. This hypothesis is supported by Valladares et al. (Reference Valladares, Wright, Lasso, Kitajima and Pearcy2000), but Rozendaal et al. (Reference Rozendaal, Hurtado and Poorter2006) proposed that key functional attributes of shade-tolerant species should be more phenotypically plastic since they grow in highly varied light environments. Thus, no consensus exists as higher, similar, and lower plasticity has been found in light-demanding species compared to shade-tolerant species (Valladares and Niinemets Reference Valladares and Niinemets2008).

On the other hand, the composition and abundance of insect communities are affected by abiotic conditions that generate tree gaps (gaps vs. closed canopy), causing a filter that excludes many species (Richards and Windsor Reference Richards and Windsor2007). Previous studies on the effects of light environments on insect herbivores have reported increased abundance and richness in full sun environments, due to warmer temperatures of the gaps that can increase the metabolism and activity of insects (Łukowski et al. Reference Łukowski, Giertych, Zadworny, Mucha and Karolewski2015). However, some studies document increased abundance and feeding in closed canopy environments as well (Karolewski et al. Reference Karolewski, Giertych, Żmuda, Jagodziński and Oleksyn2013). Therefore, the specific way in which insects respond to changes in solar radiation on their host remains open to debate.

We conducted a reciprocal transplant experiment under natural conditions to assess the leaf attributes plasticity of plants with different degrees of shade tolerance (three light-demanding and three shade-tolerant plant species) and their relationships with insect herbivores. We hypothesise that shade-tolerant plant species should have greater phenotypic plasticity than light-demanding species as a result of changing light availability (Rozendaal et al. Reference Rozendaal, Hurtado and Poorter2006). Plasticity of structural and physiological traits was evaluated and subsequently related to insect herbivory. In addition, insects were collected from the experimental sites to learn about these communities at each site. The study questions were: (1) Which foliar traits show greater phenotypic plasticity? (2) Is herbivore damage greater in light- or shade-tolerant species? (3) Is phenotypic plasticity in foliar traits associated with the amount of leaf tissue consumed? (4) Is the abundance of insects on plant species different in gaps in closed canopy sites?

Materials and methods

Study area

The study was conducted at the Universidad Autónoma Nacional de México (UNAM) in Estación de Biología Tropical Los Tuxtlas (18°30′ N, 95°10′ W) in the northern part of the Los Tuxtlas region of Mexico. This area covers an altitudinal range of 150–700 m where the predominant vegetation type is tropical rainforest. Mean annual temperature and precipitation are 27°C and 4,700 mm, respectively (Cornejo-Tenorio et al. Reference Cornejo-Tenorio, Manríquez and Colín2019). Lateritic soils including luvisol and acrisol predominate in up lands, while deep, fertile soils with high organic matter such as vertisol, feozem, and litosol predominate in the coastal plain (Cornejo-Tenorio et al. Reference Cornejo-Tenorio, Manríquez and Colín2019). The dynamics of gaps created by falling branches and trees are fundamental for forest regeneration in the hot and humid tropics (Matsuo et al. Reference Matsuo, Martínez-Ramos, Bongers, van der Sande and Poorter2021).

Study sites

We identified five gaps in the study site, ranging between 40 m2 and 180 m2 in area and separated by at least 50 m (Figure S1). In each gap, we selected a closed canopy area located 20–25 m from the gap edge. We monitored air temperature, relative humidity (10:00 am–12:00 pm), and canopy cover every two months for one year in all 10 experimental sites (five gaps and five closed canopy sites). We used a Kestrel micro-meteorological station (Model 5500, México) to measure air temperature and relative humidity and a hemispherical densitometer to assess canopy cover (Forestry Supply, Model A, USA). All measurements were done in the centre of the gaps where the experimental plants were located to the extent possible. On average, canopy coverage under the closed canopy was 75.9% ± 10.1% and in gaps was 29.9% ± 12%. The relative humidity (95.4 ± 3.9 and 94.4 ± 4.6 for closed canopy and gap sites, respectively) and air temperature (24.9 ± 2.94 and 24.7 ± 2.86 for closed canopy and gap sites, respectively) were similar in the two environments (Lu et al. Reference Lu, Zhu, Zhang, Fang, Sun, Zhu and Wang2023).

Study species

Fabaceae and Moraceae (Fabidae) and Rubiaceae (Lamiidae) are the three most prominent plant families in Los Tuxtlas (Cornejo-Tenorio et al. Reference Cornejo-Tenorio, Manríquez and Colín2019). These three families include species with light-demanding and shade-tolerant species. We selected two species from each of these three families, pairing a light-demanding and shade-tolerant species to account for phylogenetic relatedness, at least in part, and considering that reciprocal wood density (WD) correlates positively with growth rate and regeneration mode of woody species in tropical rainforest (King et al. Reference King, Davies, Tan and Noor2006; Chave et al. Reference Chave, Coomes, Jansen, Lewis, Swenson and Zanne2009). We used data from the global WD database (Zanne et al. Reference Zanne, Lopez-Gonzalez, Coomes, Ilic, Jansen, Lewis, Miller, Swenson, Wiemann, Chave and Lopez-Gonzalez2009) to select the six species. From Rubiaceae, we selected Palicourea faxlucens (Lorence and Dwyer) Lorence (WD = 0.36) and Faramea occidentalis (L.) A. Rich. (WD = 0.55), which show a 52% difference in WD. From Fabaceae, we paired Pterocarpus rohrii Vahl (WD = 0.32) and Cynometra retusa Britton and Rose (WD = 0.85) with a 165% difference in WD. From Moraceae, we chose Poulsenia armata (Miq.) Standl. (WD = 0.4) and Pseudolmedia glabrata (Liebm.) C.C. Berg (WD = 0.61) with a 53% difference in WD.

Experimental design

In March 2017, we selected 40 saplings (20 cm ≤ 35 cm in height) of each focal species within a 10 m radius of 10 parental trees. The selected parental trees were at least 30 m away from other conspecifics. Each of the 240 (40 individuals × six species) saplings was transplanted into 5 L pots and kept under the parental tree canopy for 101 days to acclimate (Delph Reference Delph2017). By June 2017, 152 out of the 240 saplings were alive, and we distributed them in the experimental sites (gaps and closed canopy sites) balancing as much as possible the number of saplings of each species in each site. The actual number of saplings at each site ranged between 15 and 17, and there were no fewer than two individuals of each species in each site (with the exception of one with a single sapling of Pa. faxlucens); the maximum number of saplings of a single species at any site was four. The total number of saplings of each species ranged between 23 and 28.

Leaf functional traits

After 276 days in the experimental sites (March 2017–March 2018), we recorded eight leaf traits from all surviving saplings. Functional traits were measured in the middle region of each sapling in the experiment. The thickness of the leaf blade was taken with a digital calliper (MDC-1 MX, Chicago, USA). We used a portable chlorophyll metre to estimate chlorophyll content (atLEAF, Chicago, USA), and SPAD units were transformed into concentration units (mg/cm2) following the linear model proposed by Zhu et al. (Reference Zhu, Tremblay and Liang2012). Leaf toughness, measured as (g/cm2) required to break the leaf blade, was estimated with a penetrometer (KSE-2006072, Mexico). We kept the leaf blade fully extended between two pieces (7 cm × 7 cm) of plexiglass (3 mm thick) with a central hole (1 cm diameter), and the rod of the penetrometer held vertically, avoiding the first- and second-order veins, and then pressed firmly to perforate the blade. We used a rod with a diameter of 3 mm for all species except Pt. rohrii, for which we used a rod with a diameter of 5 mm because of its softer leaves. The measurements were later transformed to compare with those of the other five species. We estimated the fresh leaf blade area, fresh leaf mass, and dry mass with a portable flatbed scanner (CI-202 Bio-Science, Boston, USA). In addition, we dried the leaves in the oven at 60°C for 72 h to measure dry mass. To estimate the specific leaf area (SLA, cm2/g), we divided the fresh leaf area by the dry mass.

Water content of leaves and soil nutrients

To estimate the water content of the leaves (g g−1), we calculated the difference between fresh and dry masses and then divided by the dry mass and multiplied by one hundred. For each species at each site, we collected 10 intact leaves from each marked plant. The nitrogen and carbon contents (% of dry mass) were measured with an automated combustion analyser (TruSpec CN, Leco Corporation 2002, Michigan, USA) in the soil, water, and plant chemical analysis laboratory at Instituto de Ecología (INECOL).

Leaf herbivory

We marked all intact leaves of each plantlet with metal rings in June 2017 and every two months thereafter from June 2017 to March 2018. We also recorded cumulative evidence of herbivory following the method by Dirzo and Domínguez (Reference Dirzo, Domínguez, Bullock, Mooney and Medina1995) for non-destructive quantification. We accounted for damage left by chewing herbivores (incomplete margins, perforations, and missing areas inside the leaf blade) and recorded areas scraped off the surface of the leaf (e.g. by miners or suckers). The following damage categories were used: zero (intact leaves), one (leaves with barely perceptible damage and up to 6% of the leaf area), two (more than 6% and up to 12% in damage), three (12%–25%), four (25%–50%) and five (more than 50% in damage). The score for each leaf was used to calculate an index of damage (ID) as

$$ID = \mathop \sum \limits_{i = 0}^5 \left( {{x_i}{N_i}} \right)N$$

where X i is the i scores of damage (0 to 5), n i is the frequency of leaves with score X i , and N is the total number of scored leaves. The herbivory index was transformed into a percentage according to Ruiz-Guerra et al. (Reference Ruiz-Guerra, Nieves-Silva and Guevara2017). Specifically, this method is based on the percentage of average expected herbivory (EH) for each category of damage:

$$EH{\rm{\;}}\left( {\rm{\% }} \right) = {H_{i{\rm{\;}}max}} {{{{H_{i{\rm{\;}}max}} - {H_{i{\rm{\;}}min}}}} \over {2}}$$

where H i max and H i min correspond to the upper and lower asymptotic limit of herbivory for each category of damage, respectively. In this way, we obtained the expected average herbivory percentages of 0%, 3%, 9%, 18.5%, 37.5%, and 75% for damage categories 0–5, respectively. Finally, through a cubic linear regression with an intercept adjusted to zero, the herbivory percentage was obtained for any value of the index of damage (ID):

$$Herbivory = {\rm{\;}}\left( {\rm{\% }} \right) = 5.6131{\rm{\;}}ID - 2.4505{\rm{\;}}I{D^2} + 0.8691{\rm{\;}}I{D^3}$$

Insect community

Insect sampling at all sites was carried out in March, June, and August 2018 during dry and rainy seasons in the morning (09:00–12:00 h) and evening (21:00–24:00 h). During each sampling event, five randomly selected trees of the study species (2–8 m height) were firmly hit five times (without fatally damaging the branches) using a stick, and all falling arthropods were collected in a conical 1 m2 beating sheet emptying into a 50 ml container with 10 ml of ethanol. All taxa were identified to the order level and classified according to their feeding guilds by taxonomist María Luisa Castillo (MLC) from INECOL (Cibrián et al. Reference Cibrián, Méndez, Campos, Yates and Flores1995; Buck et al. Reference Buck, Woodley, Borkent, Wood, Pape, Vockeroth, Michelsen, Marshall, Brown, Borkent and Cumming2009).

Phenotypic plasticity index

To estimate the phenotypic plasticity of the species found in gaps versus closed canopy habitats, we modified the procedure by Valladares et al. (Reference Valladares, Wright, Lasso, Kitajima and Pearcy2000). The plasticity index was calculated as the difference between the trait value in the closed canopy habitat and its value in the gaps, divided by the largest of the two values. We calculated all possible combinations between shade and light environments for each of the six species. We kept track of the identity of the sites where the plant belonged in each calculation to use it as a random factor, together with the specific identity of the plants. Calculated in this way, positive values of the plasticity index will indicate that the trait is more variable in the shaded environment, while negative values indicate greater plasticity in gaps.

Statistical analysis

To evaluate whether the values of the phenotypic plasticity index were statistically different from zero, we used a mixed effects model in which tree species (six levels) was the fixed factor, and the identity of the pair of sites for plasticity estimates was defined as a random factor to control for the variance for each species and avoid pseudo-replication. In all cases, the variance was modelled within the fixed factor with a constant variance equal to one, while we used the raw estimated variances for the random factor. To explore the overall pattern of phenotypic plasticity, we used non-metric multidimensional scaling between species and traits. We also used cluster analysis with the Ward clustering method and Euclidian distances.

To evaluate the effect of the light environment and the specific identity of the plants on cumulative herbivory, we used a mixed effects model with repeated measurements. The fixed factors were habitat (two levels) and species (six levels) with time as a covariate. The identity of the gap and closed canopy sites was used as a random variable analysed within each time (repeated measures model). A logarithmic transformation of the percentage of herbivory was used.

To evaluate the correlation between the phenotypic plasticity of the plant traits and cumulative herbivory in the two light environments, we used a co-inertia analysis based on principal components. The co-inertia analysis, like other multivariate techniques including canonical correlation and redundancy analysis, seeks to correlate two data matrixes that share the identity of the observation units; however, the co-inertia analysis is more robust when dealing with collinearity among variables within each of the matrixes (Dray et al. Reference Dray, Chessel and Thioulouse2003). We used a Monte Carlo test to establish the significance of the observed correlation between the two tables (Heo and Gabriel Reference Heo and Gabriel1997).

To analyse possible differences in the abundance of invertebrate trophic guilds found in the two environments, we used a contingency table with six columns (trophic guilds) and four rows (environments in daytime and night-time). For the purpose of this analysis, we summed all samples for daytime and night in each environment. All analyses were done in R version 4.3.2 (R Core Team 2023).

Results

Phenotypic plasticity

Non-metric multidimensional scaling found that SLA and leaf water content were the most variable traits among species (Figure 1). The intraspecific variation between environments, although limited, suggested a concordant increase in nitrogen and chlorophyll in gaps.

Figure 1. Functional traits of six woody, tropical rainforest tree species in Mexico. The non-metric multidimensional scaling plot in the central panel highlights clusters of each species: Cynometra retusa = Cy. retusa (green) and Pterocarpus rohrii = Pt. rohrii (red) in Fabaceae, Pseudolmedia glabrata = Ps. glabrata (blue) and Poulsenia armata = Po. armata (orange) in Moraceae, and Faramea occidentalis = Fa. occidentalis (purple) and Palicourea faxlucens = Pa. faxlucens (magenta) in Rubiaceae. Solid lines encircle points representing saplings grown under a closed canopy, and dotted lines surround points from saplings in gaps. Peripheral panels represent the phenotypic plasticity index for each foliar trait (SLA = specific leaf area). The data are presented as (values in closed canopy) – (values in gaps). Means, whiskers, and error bars (standard error) in the grey section represent traits with higher average values under a closed canopy. Means, whiskers, and error bars in the white section represent traits with higher average values in gaps. *P = 0.01, **P = 0.001, ***P = 0.0001 significance level.

Leaves of shade-tolerant species were on average 11% tougher when grown under the canopy of the forest compared to when they were grown in gaps (t = 4, df = 26, P < 0.001). Nonetheless, when separated by species, the leaf toughness of Cy. retusa and Fa. occidentalis increased by 13.6% (t = 4.2, df = 34, P < 0.001), while there was no significant difference for Ps. glabrata (t = 0.3, df = 68, P = 0.73). In contrast, the leaf toughness of the light-demanding species did not change between light environments (t < 0.1, df = 23, P > 0.05).

Similarly, two out of the three shade-tolerant species (Cy. retusa and Fa. occidentalis) developed thicker leaves (11% and 7%), respectively (Table S1), under closed canopy, compared to leaf thickness in gaps (t = 3.7, df = 23, P = 0.001). The leaf thickness of Ps. glabrata did not differ significantly between environments (t = 0.5, df = 68, P = 0.59). There were also mixed responses for the light-demanding species. Poulsenia armata leaf thickness did not differ between environments (t = 1.6, df = 68, P = 0.10) but increased in Pt. rohrii and Pa. faxlucens (t > 2.8, df = 68, P < 0.005). Leaves of Pt. rohrii were 18% thicker under closed canopy than in gaps, meanwhile Pa. falcons had 33% thicker leaves in the gaps than closed canopy forest.

The leaf water content of Ps. glabrata (t = 0.4, df = 68, P = 0.71) did not change between environments, while for the two other shade-tolerant species, it changed (t = 10.2, df = 34, P < 0.001). The leaf water content of Cy. retusa was 6% higher in the gaps than under closed canopy (Table S1). In contrast, leaf water content was 28% higher in Fa. occidentalis under closed canopies than in gap environments. Leaf water content increased under forest canopies for the light-demanding species Poulsenia armata (22%) and Pa. faxlucens (20%) compared to gaps (t = 15.2, df = 34, P < 0.001). There was no change between environments in Pt. rohrii (t = 0.5, df = 68, P = 0.60).

Specific leaf area in light-demanding species was consistently higher in gaps than in closed canopy environments (t = 22.3, df = 23, P < 0.001). The specific leaf area of Pt. rohrii increased by 33% in gaps and increased by 19% and 17% in Po. armata and Pa. faxlucens, respectively, in gaps (Table S1). In contrast, the shade-tolerant species Cy. retusa (19%) and Fa. occidentalis (4%) had higher specific leaf area under closed canopies compared to gaps (t = 11.4, df = 34, P < 0.001), while Ps. glabrata (17%) showed the opposite response (t =12, df = 68, P < 0.001).

Chlorophyll content showed the same pattern as leaf water content in shade-tolerant species. The chlorophyll content did not change in Ps. glabrata between environments (t = 1.6, df = 68, P = 0.08), while Cy. retusa and Fa. occidentalis had opposite responses. The chlorophyll content of Cy. retusa increased by 8% when grown in the gaps compared with closed canopies (t = 2.3, df = 68, P = 0.012), while the chlorophyll content was 14% higher in Fa. occidentalis under closed canopies compared to gaps (t = 4.3, df = 68, P < 0.001) (Table S1). Similarly, results were mixed for light-demanding species. The chlorophyll content of Pa. faxlucens did not change between environments (t = 1.7, df = 68, P < 0.09), while Pt. rohrii and Po. armata had 49% and 13% more chlorophyll in gaps and closed canopy forest (t > 5.5, df = 34, P < 0.001) (Table S2).

The three light-demanding species had consistently higher leaf carbon content (4%–10%) when grown in gaps than when grown under forest canopies (t > 9.4, df = 34, P < 0.001) (Table S1). Similarly, the nitrogen contents of Pt. rohrii (27%) and Pa. faxlucens (32%) were higher in gaps than under closed canopy (t > 10.3, df = 34, P < 0.001). In contrast, the nitrogen content of Po. armata did not change between environments (t = 0.4, df = 68, P = 0.65). Because of that, the C:N ratio in Po. armata also did not change between gaps and closed forest canopy (t = 0.7, df = 68, P = 0.46), while the C:N ratio was higher (20%–31%) in the other two light-demanding species under closed forest canopy compared to gaps (t > 6.3, df = 68, P < 0.001). In shade-tolerant species, the carbon content changed significantly between environments only in Ps. glabrata (2%, t = 2.1, df = 68, P = 0.048), while the nitrogen content changed significantly in all three species, albeit with mixed responses. In Cy. retusa (7%) and Ps. glabrata (9%), the nitrogen content was higher when grown in gaps than under closed canopy. In contrast, Fa. occidentalis (7%) had higher nitrogen content under closed canopy compared to gaps (t = 2.4, df = 68, P = 0.017). Consequently, the C:N ratios of shade-tolerant species were variable. The C:N ratio was higher in Cy. retusa (7%) and Ps. glabrata (9%) in closed canopies than in gap environments (t = 3.5, df = 34, P = 0.001), while the C:N ratio was higher (7%) in Fa. occidentalis when grown in the gaps compared to the closed forest canopies (t = 2.6, df = 68, P = 0.01) (Table S1).

A cluster analysis of plant trait plasticity found that Fa. occidentalis and Po. armata were similarly variable (dissimilarity less than 30%) (Figure 2). Also, with a dissimilarity of 40%, Cy. retusa and Ps. glabrata formed a second pair of species with similar responses and an average dissimilarity of ca. 60% in relation to the cluster with Fa. occidentalis and Po. armata. The main difference between these two pairs was in the phenotypic plasticity of specific leaf area. Finally, Pt. rohrii and Pa. faxlucens were 90% dissimilar to the other four species. Coincidentally, the groups corresponded to high, mid, and low WD.

Figure 2. Grouping of six tree species of the tropical rainforest in Mexico under two light environments based on the plasticity of eight functional leaf traits. Cynometra retusa = Cy. retusa, Pterocarpus rohrii = Pt. rohrii, Pseudolmedia glabrata = Ps. glabrata, Poulsenia armata = Po. armata, Faramea occidentalis = Fa. occidentalis, and Palicourea faxlucens = Pa. faxlucens.

Herbivory levels

Leaf damage by herbivores over 259 days differed significantly among species, and there was interaction with the type of environment (Χ 2 = 13.96, df = 6, P < 0.03, Figure 3). In the closed canopy habitat, average herbivory ranged from 3.4% to 6.1%, while in the gaps, it ranged between 5.9% and 14.8%. Herbivory was higher in forest canopy sites for Ps. glabrata (Moraceae), Pa. faxlucens (Rubiaceae), and both species in the Fabaceae (Cy. retusa and Pt. rohrii), compared to the herbivory observed in the closed canopy habitat (t > 3.2, P < 0.002) (Figure 3). For Po. armata and Fa. occidentalis (Moraceae and Rubiaceae, respectively), there were no significant differences in herbivory between habitat types (t < 0.4, P > 0.33).

Figure 3. Cumulative herbivory over 259 days of field exposure for six tree species of the tropical rainforest in Mexico in two light environments. Cynometra retusa = Cy. retusa, Pterocarpus rohrii = Pt. rohrii, Pseudolmedia glabrata = Ps. glabrata, Poulsenia armata = Po. armata, Faramea occidentalis = Fa. occidentalis, and Palicourea faxlucens = Pa. faxlucens.

Correlation of phenotypic plasticity and insect herbivory

Based on the co-inertia analysis, we observed an overall correlation coefficient of 64% (P = 0.021) between leaf trait plasticity and the percentage of herbivory observed in gaps and closed canopy habitats. Species with a high C:N ratio in closed canopy forests but a low C:N ratio in gaps (Pa. faxlucens, Ps. glabrata, and Pt. rohrii) were more heavily attacked by herbivores in gaps. In contrast, herbivory on Po. armata, Fa. occidentalis, and Cy. retusa did not differ between environments. They also had the least variable C:N ratios.

Insect community

Overall, we collected 1,202 insects from seven different feeding guilts (Table S3). They were similarly abundant in closed canopy sites (607) and gaps (595). Herbivores collected at night accounted for 59% and 65% of the insects in closed canopies and gaps, respectively. The abundances of trophic guilds changed significantly between habitat types (X 2 = 111.2, df = 15, P < 0.001). The residual analysis demonstrated that herbivores were overrepresented in the closed canopy sites during the night census but underrepresented in the morning census (z = 2.4, P = 0.016 and z = 2.7, P = 0.007, respectively). In contrast, abundances of herbivores in gaps were no different than by chance (z < 0.1, P = 0.92). However, the overall abundances of herbivores were similar in closed canopy sites and gaps, respectively. Detritivorous taxa in closed canopy sites, unlike herbivores, were overrepresented in the daytime (z = 6.7, P < 0.001) and underrepresented at night (z = 3.2, P = 0.001); however, their abundances did not differ from random expectation in gaps (z < 1.4, P > 0.161). Omnivores in closed canopy sites were overrepresented in the night census (z = 3.3, P < 0.001) and underrepresented during daytime in gaps (z = 2.1, P = 0.035). Also, mycetophagus taxa were overrepresented in gaps during daytime (z = 2.6, P = 0.009). Overall, all trophic guilds were similarly abundant in different habitat types (z = 1.9, P > 0.057).

Discussion

We found that six Mexican tropical rainforest tree species differed markedly in the phenotypic plasticity of eight leaf traits. Two of the light-demanding species, which also had the lowest wood densities, had the most phenotypically plastic responses. Specific leaf area and carbon contents were highly variable in Pt. rohrii, and leaf thickness and nitrogen content were plastic in Pa. faxlucens. The Moraceae species Ps. glabrata and Po. armata, along with Pt. rohrii and Pa. faxlucens, had higher specific leaf area in gaps than under the closed canopy. Herbivory of Po. armata was significantly higher in gaps than under closed canopies. On the other hand, C:N

ratios do not differ between light environments, yet C:N ratios are lower in low-light environments (Luo et al. Reference Luo, Li, Guo, Li and Jin2022). The carbon gain hypothesis posits that saplings tend to maximise net carbon gain to perform optimally in low-light conditions, for example, to alter plant morphology to maximise light capture (de Mello Prado and da Silva Reference de Mello Prado and da Silva2017).

Phenotypic plasticity of C:N ratios was high in Cy. retusa and Ps. glabrata, and higher trait values were observed under a closed canopy. The high C:N ratio under a closed canopy translates into low nutritional values of the leaves for herbivores (Coley and Barone Reference Coley and Barone1996). Because the overall abundance of herbivores between environments showed did not differ significantly, the evidence suggests that these species shifted their antiherbivore defence or could have differed in their host specialisation, size, etc. Defence syndromes are defined as the orchestrated expression of functional traits to minimise the impact of herbivores (Agrawal and Fishbein Reference Agrawal and Fishbein2006). Recent studies find that defence syndromes range from tolerance to herbivory. Physical and chemical defences, along with low nutritional quality, deter herbivores (Ruiz-Guerra et al. Reference Ruiz-Guerra, García, Velázquez-Rosas, Angulo and Guevara2021; Gianoli et al. Reference Gianoli, Salgado-Luarte and Escobedo2023).

Overall, we observed 47% more herbivory in gaps than under closed canopy. This is consistent with the findings by Piper et al. (Reference Piper, Altmann and Lusk2018) who, in a meta-analysis, found almost 50% more herbivory in tropical forest gaps compared to closed canopy environments, a pattern also reported by De la Cruz and Dirzo (Reference De la Cruz and Dirzo1988), Boege and Dirzo (Reference Boege and Dirzo2004), and Ruiz-Guerra et al. (Reference Ruiz-Guerra, García, Velázquez-Rosas, Angulo and Guevara2021) in a Mexican tropical rainforest.

Our results contradict the findings of Rozendaal et al. (Reference Rozendaal, Hurtado and Poorter2006), who concluded that shade-tolerant species are more phenotypically variable than light-demanding species. We observed the greatest phenotypic plasticity in two of the light-demanding species. This agrees with the hypothesis of increased phenotypic plasticity in resource-rich environments (Lortie and Aarssen Reference Lortie and Aarssen1996) and with Valladares et al. (Reference Valladares, Wright, Lasso, Kitajima and Pearcy2000) who investigated phenotypic plasticity in 16 Psychotria species on Barro Colorado Island. Nonetheless, we observed that each species had some traits that differed between environments, and the most frequent differences are seemingly related to the species’ WD. WD is arguably a surrogate for growth rate (King et al. Reference King, Davies, Tan and Noor2006; Chave et al. Reference Chave, Coomes, Jansen, Lewis, Swenson and Zanne2009) and plant regeneration mode (light-demanding and shade-tolerant species). Specific leaf area and high nitrogen content were the most variable in the two species with the lowest WD, Pt. rohrii and Pa. faxlucens. The high values of these traits in gaps indicate high photosynthesis and nutrient assimilation and are consistent with the high levels of herbivory observed in these species.

In general, the carbon content of light-demanding species was highly variable between environments and was generally higher when they grew under forest canopy sites. However, leaf toughness did not change significantly between light environments. This suggests that the increase in carbon content in gaps may be in the form of non-structural carbon compounds such as starch, sucrose, and fructose (Hoch et al. Reference Hoch, Richter and Körner2003). In Cy. retusa and Fa. occidentalis, phenotypic plasticity was observed in leaf toughness. Leaves were tougher when grown under a forest canopy. In contrast, carbon content did not change between light environments, suggesting at least a partial substitution of some structural carbon compounds accumulated under the closed canopy of the forest for non-structural carbon compounds in gaps. One way in which this relocation of compounds may occur is by the incorporation of soluble sugars from the cell apoplast into structural defences (Zhang et al. Reference Zhang, Yan, Wang and Zhu2021).

In conclusion, we demonstrate that phenotypic plasticity in foliar traits of woody tropical rainforest species occurred in light-demanding and shade-tolerant species, and the most frequently observed response patterns seem to be associated with the species’ WD. The trait is commonly used as a surrogate for growth rate and regeneration mode. Consistent with the resource availability hypothesis (Gianoli and Salgado-Luarte Reference Gianoli and Salgado-Luarte2017), we found that herbivory was higher in gaps than in closed canopies. We hypothesise that this is a consequence of an environmentally mediated shift from herbivore tolerance in gaps to chemical defence-related herbivore resistance (or low nutritional quality) under a closed canopy.

Supplementary material

To view supplementary material for this article, please visit https://doi.org/10.1017/S0266467424000233

Acknowledgements

We thank Santiago Sinaca, Martín de los Santos, Salvador González, and Ismael Valdivieso for their assistance in the field. Likewise, we thank Sandra Rocha for her support and advice in the carbon and nitrogen determinations at the INECOL chemical analysis laboratory. Finally, we appreciate the collaboration of all the staff of the Estación de Biología Tropical Los Tuxtlas during the fieldwork.

Financial support

This study was supported by the CONAHCYT research grant awarded to DACZ (609138) and the fiscal resources of R. Guevara (INECOL-10466).

Competing interests

The authors declare none.

References

Adams, WW III, Stewart, JJ, Polutchko, SK, Cohu, CM, Muller, O and Demmig-Adams, B (2023) Foliar phenotypic plasticity reflects adaptation to environmental variability. Plants 12, 2041.CrossRefGoogle ScholarPubMed
Adler, PB, Salguero-Gómez, R, Compagnoni, A, Hsu, JS, Ray-Mukherjee, J, Mbeau-Ache, C and Franco, M (2014) Functional traits explain variation in plant life history strategies. Proceedings of the National Academy of Sciences 111, 740745.CrossRefGoogle ScholarPubMed
Agrawal, AA (2001) Phenotypic plasticity in the interactions and evolution of species. Science 294, 321326. https://doi:10.1126/science.1060701 CrossRefGoogle ScholarPubMed
Agrawal, AA and Fishbein, M (2006) Plant defense syndromes. Ecology 87, S132S149.CrossRefGoogle ScholarPubMed
Baraza, E, Zamora, R and Hódar, JA (2010) Species-specific responses of tree saplings to herbivory in contrasting light environments: an experimental approach. Écoscience 17, 156165.CrossRefGoogle Scholar
Boege, K and Dirzo, R (2004) Intraspecific variation in growth, defense and herbivory in Dialium guianense (Caesalpiniaceae) mediated by edaphic heterogeneity. Vegetation 175, 5969.Google Scholar
Buck, M, Woodley, NE, Borkent, A, Wood, DM, Pape, Th, Vockeroth, JR, Michelsen, V and Marshall, SA (2009) Key to Diptera Families - Adults. In Brown, BV, Borkent, A, Cumming, JM. (eds), Manual of Central American Diptera Vol 1. Ottawa: NRC Research Press, pp. 95144.Google Scholar
Chave, J, Coomes, D, Jansen, S, Lewis, SL, Swenson, NG and Zanne, AE (2009) Towards a worldwide wood economics spectrum. Ecology Letters 12, 351366.CrossRefGoogle ScholarPubMed
Cibrián, TD, Méndez, JT, Campos, MR, Yates, BHO III and Flores, JEL (1995) Insectos Forestales de México/Forest Insects of México. Universidad Autónoma de Chapingo. SARH Subsecretaria Forestal y de Fauna Silvestre, México. USDA, Forest Service, Natural Resources Canada. North American Forestry Commission, FAO. Pub 6. (pp. 453).Google Scholar
Coley, PD and Barone, JA (1996) Herbivory and plant defenses in tropical forests. Annual Review of Ecology and Systematics 27, 305335.CrossRefGoogle Scholar
Cornejo-Tenorio, G, Manríquez, GI and Colín, SS (2019) Flora de Los Tuxtlas: guía ilustrada. Universidad Nacional Autónoma de México.Google Scholar
De la Cruz, M and Dirzo, R (1988) A survey of the standing levels of herbivory in seedlings from a Mexican rain forest. Biotropica 19, 98106.CrossRefGoogle Scholar
de Mello Prado, R and da Silva, GP (2017) Ecological response to global change: Changes in C: N: P stoichiometry in environmental adaptations of plants. Plant Ecology: Traditional Approaches to Recent Trends, 147.Google Scholar
Delph, LF (2017) The study of local adaptation: a thriving field of research. Journal of Heredity 109, 12. https://doi:10.1093/jhered/esx099 CrossRefGoogle Scholar
DeWitt, TJ and Scheiner, SM (2004) Phenotypic Variation from Single Genotypes: A Primer. In DeWitt, TJ and Samuel, MS (eds), Phenotypic Plasticity: Functional and Conceptual Approaches. New York, USA: Oxford Academic Press, pp. 19.CrossRefGoogle Scholar
Dirzo, R and Domínguez, CA (1995) Plant–herbivore interactions in Mesoamerican tropical dry forests. In Bullock, S. H., Mooney, H. A. and Medina, E. (eds), Seasonal dry tropical forests. Cambridge, UK: Cambridge University Press, pp. 304325 CrossRefGoogle Scholar
Dray, S, Chessel, D and Thioulouse, J (2003) Co-inertia analysis and the linking of ecological data table. Ecology 84, 30783089.CrossRefGoogle Scholar
Dupuy, JM and Chazdon, RL (2008) Interacting effects of canopy gap, understory vegetation and leaf litter on tree seedling recruitment and composition in tropical secondary forests. Forest Ecology and Management 255, 37163725 CrossRefGoogle Scholar
Falster, DS, Duursma, RA and FitzJohn, RG (2018) How functional traits influence plant growth and shade tolerance across the life cycle. Proceedings of the National Academy of Sciences 115, E6789E6798. https://doi.org/10.1073/pnas.171404411CrossRefGoogle ScholarPubMed
Gianoli, E and Salgado-Luarte, C (2017) Tolerance to herbivory and the resource availability hypothesis. Biology Letters 13, 20170120.CrossRefGoogle ScholarPubMed
Gianoli, E, Salgado-Luarte, C and Escobedo, VM (2023) Shade tolerance and the relationship between herbivory and light availability. International Journal of Plant Sciences 184, 519524.CrossRefGoogle Scholar
Heo, M and Gabriel, KR (1997) A permutation test of association between configurations by means of the RV coefficient. Communications in Statistics - Simulation and Computation 27, 843856.Google Scholar
Hoch, G, Richter, A and Körner, C (2003) Non-structural carbon compounds in temperate forest trees. Plant, Cell & and Environment 26, 10671081.CrossRefGoogle Scholar
Karolewski, P, Giertych, MJ, Żmuda, M, Jagodziński, AM and Oleksyn, J (2013) Season and light affect constitutive defenses of understory shrub species against folivorous insects. Acta Oecologica 53, 1932.CrossRefGoogle Scholar
King, DA, Davies, SJ, Tan, S and Noor, NS (2006) The role of wood density and stem support costs in the growth and mortality of tropical trees. Journal of Ecology 94, 670680.CrossRefGoogle Scholar
Laughlin, DC (2023) Plant strategies: the demographic consequences of functional traits in changing environments. Oxford University Press.CrossRefGoogle Scholar
Lortie, CJ and Aarssen, LW (1996) The specialization hypothesis for phenotypic plasticity in plants. International Journal of Plant Sciences 157, 484487.CrossRefGoogle Scholar
Lu, D, Zhu, J, Zhang, G, Fang, S, Sun, Y, Zhu, C, … & Wang, GG (2023) A forest gap is not forever: Towards an objective standard to determine when a gap is considered closed in temperate forests. Agricultural and Forest Meteorology 340, 109598.CrossRefGoogle Scholar
Łukowski, A, Giertych, MJ, Zadworny, M, Mucha, J and Karolewski, P (2015) Preferential feeding and occupation of sunlit leaves favors defense response and development in the flea beetle, Altica brevicollis coryletorum–a pest of Corylus avellana . PloS One 10, e0126072.CrossRefGoogle ScholarPubMed
Lundgren, MR and Des Marais, DL (2020) Life history variation as a model for understanding trade-offs in plant–environment interactions. Current Biology 30, R180R189.CrossRefGoogle Scholar
Luo, G, Li, J, Guo, S, Li, Y and Jin, Z (2022) Photosynthesis, nitrogen allocation, non-structural carbohydrate allocation, and C:N:P stoichiometry of Ulmus elongata seedlings exposed to different light intensities. Life 12, 1310.CrossRefGoogle Scholar
Matsuo, T, Martínez-Ramos, M, Bongers, F, van der Sande, MT and Poorter, L (2021) Forest structure drives changes in light heterogeneity during tropical secondary forest succession. Journal of Ecology 109, 28712884.CrossRefGoogle ScholarPubMed
Piper, FI, Altmann, SH and Lusk, CH (2018) Global patterns of insect herbivory in gap and understory environments, and their implications for woody plant carbon storage. Oikos 127, 483496.CrossRefGoogle Scholar
Poorter, L, Amissah, L, Bongers, F, Hordijk, I, Kok, J, Laurance, SG, … & van der Sande, MT (2023) Successional theories. Biological Reviews 98, 20492077.CrossRefGoogle ScholarPubMed
Poorter, L and Bongers, F (2006) Leaf traits are good predictors of plant performance across 53 rain forest species. Ecology 87, 17331743.CrossRefGoogle ScholarPubMed
R Core Team. (2023) R: a language and environment for statistical computing. Viena: R Foundation for Statistical Computing.Google Scholar
Richards, LA and Windsor, DM (2007) Seasonal variation of arthropod abundance in gaps and the understory of a lowland moist forest in Panama. Journal of Tropical Ecology 23, 169176.CrossRefGoogle Scholar
Rozendaal, DMA, Hurtado, VH and Poorter, L (2006) Plasticity in leaf traits of 38 tropical tree species in response to light; relationships with light demand and adult stature. Functional Ecology 20, 207216.CrossRefGoogle Scholar
Ruiz-Guerra, B, García, A, Velázquez-Rosas, N, Angulo, D and Guevara, R (2021) Plant-functional traits drive insect herbivory in a tropical rainforest tree community. Perspectives in Plant Ecology, Evolution and Systematics 48, 125587.CrossRefGoogle Scholar
Ruiz-Guerra, B, Nieves-Silva, E and Guevara, R (2017) The role of leaf traits and bird-mediated insect predation on patterns of herbivory in a semiarid environment in central Mexico. Botanical Sciences 95, 189201.CrossRefGoogle Scholar
Scheepens, JF, Deng, Y and Bossdorf, O (2018) Phenotypic plasticity in response to temperature fluctuations is genetically variable, and relates to climatic variability of origin, in Arabidopsis thaliana . AoB PLANTS 10, ply043.CrossRefGoogle ScholarPubMed
Stiegel, S, Entling, MH and Mantilla-Contreras, J (2017) Reading the leaves’ palm: leaf traits and herbivory along the microclimatic gradient of forest layers. PloS One 12, e0169741.CrossRefGoogle ScholarPubMed
Tripathi, S, Bhadouria, R, Srivastava, P, Devi, RS, Chaturvedi, R and Raghubanshi, AS (2020) Effects of light availability on leaf attributes and seedling growth of four tree species in tropical dry forest. Ecological Processes 9, 116.CrossRefGoogle Scholar
Valladares, F (2003) Light heterogeneity and plants: from ecophysiology to species coexistence and biodiversity. Progress in botany: Genetics; Physiology; Systematics; Ecology, pp. 439–471.CrossRefGoogle Scholar
Valladares, F and Niinemets, Ü (2008) Shade tolerance, a key plant feature of complex nature and consequences. Annual Review of Ecology, Evolution, and Systematics 39, 237257.CrossRefGoogle Scholar
Valladares, F, Wright, J, Lasso, SE, Kitajima, K and Pearcy, RW (2000) Plastic phenotypic responses to light of 16 congeneric shrubs from a Panamanian rainforest. Ecology 81, 19251936.CrossRefGoogle Scholar
Zanne, AE, Lopez-Gonzalez, G, Coomes, DA, Ilic, J, Jansen, S, Lewis, SL, Miller, RB, Swenson, NG, Wiemann, MC, Chave, J and Lopez-Gonzalez, G (2009) Global Wood Density Database https://datadryad.org/stash/dataset/doi:10.5061/dryad.234.CrossRefGoogle Scholar
Zhang, T, Yan, Q, Wang, GG and Zhu, J (2021) The effects of stump size and within-gap position on sprout non-structural carbohydrates concentrations and regeneration in gaps vary among species with different shade tolerances. Ecological Processes 10, 114.CrossRefGoogle Scholar
Zhu, J, Tremblay, T and Liang, Y (2012) Comparing SPAD and atLEAF values for chlorophyll assessment in crop species, Canadian Journal of Soil Science 92, 645648.CrossRefGoogle Scholar
Figure 0

Figure 1. Functional traits of six woody, tropical rainforest tree species in Mexico. The non-metric multidimensional scaling plot in the central panel highlights clusters of each species: Cynometra retusa = Cy. retusa (green) and Pterocarpus rohrii = Pt. rohrii (red) in Fabaceae, Pseudolmedia glabrata = Ps. glabrata (blue) and Poulsenia armata = Po. armata (orange) in Moraceae, and Faramea occidentalis = Fa. occidentalis (purple) and Palicourea faxlucens = Pa. faxlucens (magenta) in Rubiaceae. Solid lines encircle points representing saplings grown under a closed canopy, and dotted lines surround points from saplings in gaps. Peripheral panels represent the phenotypic plasticity index for each foliar trait (SLA = specific leaf area). The data are presented as (values in closed canopy) – (values in gaps). Means, whiskers, and error bars (standard error) in the grey section represent traits with higher average values under a closed canopy. Means, whiskers, and error bars in the white section represent traits with higher average values in gaps. *P = 0.01, **P = 0.001, ***P = 0.0001 significance level.

Figure 1

Figure 2. Grouping of six tree species of the tropical rainforest in Mexico under two light environments based on the plasticity of eight functional leaf traits. Cynometra retusa = Cy. retusa, Pterocarpus rohrii = Pt. rohrii, Pseudolmedia glabrata = Ps. glabrata, Poulsenia armata = Po. armata, Faramea occidentalis = Fa. occidentalis, and Palicourea faxlucens = Pa. faxlucens.

Figure 2

Figure 3. Cumulative herbivory over 259 days of field exposure for six tree species of the tropical rainforest in Mexico in two light environments. Cynometra retusa = Cy. retusa, Pterocarpus rohrii = Pt. rohrii, Pseudolmedia glabrata = Ps. glabrata, Poulsenia armata = Po. armata, Faramea occidentalis = Fa. occidentalis, and Palicourea faxlucens = Pa. faxlucens.

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