Ethics statement

All materials in the present study were collected from Xishuangbanna Tropical Botanical Garden (XTBG), and none of the experimental materials was collected from national parks or other protected areas. The uses of experimental materials were permitted for scientific research by both XTBG and Xishuangbanna National Nature Reserve. No species under first-class state protection were used in this research, and they were not listed in the Inventory of Rare and Endangered Plants of China, or the Key Protected Inventory of Wild Plants of China.

Plant materials

We gathered samples of 30 fern species, including 19 terrestrial and 11 epiphytic ferns, from 13 families. The names and their ecological characteristics are presented in Table S1 in File S1. This collection was made in a seasonal tropical rainforest at the Xishuangbanna Tropical Botanical Garden (21°41′N, 101°25′E, elevation 570 m) in southern Yunnan Province, China. All species grow under the canopy of the forest, and can receive about 10% of full sunlight. The mean annual temperature is 21.7°C, and the mean annual precipitation is 1560 mm, with 80% falling during the rainy season (May to October). The fronds were collected from at least six individuals per species. All sampling and measurements were conducted from June to August in 2011.

Leaf physiology

Measurements of leaf physiology were performed on the same individuals used for our anatomical assessments. A Li-Cor 6400 portable photosynthesis system attached with a 6400-40 fluorescence chamber (Li-Cor Inc., Lincoln, NE, USA) was used to measure maximum photosynthetic rate (A_max), stomatal conductance (g_s), and transpiration rate (T_r) on 6 mature leaves from different individuals of each species. All measurements were conducted from 09:30 to 11:30 am, when CO₂ uptake was maximal and water availability was not limited. Before measurements, each leaf was exposed to a light intensity of 300 µmol m⁻² s⁻¹ for 30 min to induce the maximum stomatal opening. This light level was confirmed as the saturation point for photosynthesis of ferns in the preliminary experiments. During the measurement period, the CO₂ concentration in the chamber was set to 400 µmol mol⁻¹, with leaf temperature at 25 to 27°C, light intensity at 300 µmol m⁻² s⁻¹, flow rate at 200 mol s⁻¹ and leaf-to-air vapor pressure deficit at 0.7 to 1.0 kPa.

Leaf water content (LWC) is determined on 6 mature leaves per species from different plants. These samples were collected in the morning, and immediately determined fresh weight, and then oven-dried at 70°C for 48 h to obtain dry weight. We calculated LWC as (fresh weigh-dry weight)/fresh weight ×100.

Leaf anatomy and morphology

Six mature, undamaged leaves were collected from individual plants of each species. Each leaf was divided along the midrib. Area of one half was measured with a Li-Cor 3000A area meter (Li-Cor Inc., Lincoln, NE, USA), oven-dried at 70°C for 48 h to obtain its dry mass, and calculated its leaf mass per unit area (LMA). Another half was cleaned for 1 h in a 5% NaOH aqueous solution. Three sections of leaf lamina were excised from the top, middle, and bottom portions, stained with 1% safranin, and mounted in glycerol to obtain the vein density (D_vein). Samples were photographed at 10× magnification using a Leica DM2500 microscope (Leica Microsystems Vertrieb GmbH, Wetzlar, Germany). Vein lengths were determined from digital images via the IMAGEJ program (http://rsb.info.nih.gov/ij/). Values for D_vein were expressed as vein length per unit area.

The adaxial and abaxial epidermises were peeled from the middle portions of fresh, mature leaves, and images were made under the Leica DM2500 microscope. For each species, 6 leaves from different individuals were used for stomatal observations. Their stomata were tallied in 30 randomly selected fields. Stomatal density (SD) was calculated as the number per unit leaf area. Stomatal length (SL) was represented by the guard cell length, possibly indicating the maximum potential opening of the pore [43].

From samples of each species, the middle portions of mature leaves were fixed in FAA (formalin, acetic acid, alcohol, and distilled water, 10∶5∶50∶35, v∶v∶v∶v) for at least 24 h. They were then dehydrated in an ethanol series and embedded in paraffin for sectioning. Transverse sections, made on a Leica RM2126RT rotary microtome (Leica Inc., Bensheim, Germany), were mounted on glass slides. These tissues were examined and photographed using the Leica DM2500 microscope. Thicknesses of the cuticle (CT), upper epidermis (UET), lower epidermis (LET), mesophylls (MT), and the whole-leaf (LT) were measured at the midpoint of each transverse section with the IMAGEJ program. Six leaves per species were taken from different individuals. Leaf density (LD) was calculated as LMA/LT.

Data analysis

A phylogenetic tree for these 30 fern species was constructed based on chloroplast rbcL sequences obtained from the GenBank website (http://www.ncbi.nlm.nih.gov/genbank/). Phylogenetic analyses for each matrix were carried out using the maximum likelihood method in PAUP* v.4.0b10 [44]. Schneider et al. (2004) has integrated Colysis and major components of Microsorum into Leptochilus by using nucleotide sequences derived from three plastid loci [45]. For simplicity, the old Latin names of species in Colysis and Microsorum were used in the present study.

All statistical analyses were performed with R software v. 2.15.0 [46]. The phylogenetic signal (K-statistic) for each trait was calculated using ‘picante’ based on the R package. Such K-statistics can express the conservatism of traits. Cases where the K-value is <1 indicate convergent traits while K>1 represents that traits are more conserved than would be presumed from a Brownian expectation [47].

Relationships among variables were evaluated by both pair-wise Pearson correlations in the R package and a phylogenetically independent contrast (PIC). Possible evolutionary associations were assessed via PIC analysis, utilizing the molecular phylogenetic tree. This PIC analysis was examined with the “analysis of traits” module in Phylocom, which calculates the internal node values for continuous traits [48].

Variations in leaf traits between growth habits

Differences in growth habits can reveal variations in the availability of abiotic resources. Generally, water availability is one of the main factors that limit photosynthesis and growth of epiphytic plants [49]. Compared with terrestrial fern, epiphytic species has more resistive vascular systems, higher drought tolerance, and different anatomical features [13]. In this study, epiphytic ferns had higher values for LMA, thicknesses of whole lamina, epidermis and mesophylls than terrestrial species (Table 2). Thick leaves would be favorable in dry habitats because they can store more water [29], [42]. In addition, D_vein was lower for the epiphytic type, consistent with the pattern that epiphytic orchids have less venation than their terrestrial counterparts [26]. Torre et al. (2003) suggested that rose grown at high relative humidity (RH) has a significantly higher SD and SL, but a reduced D_vein and thinner leaves when compared to moderate RH plant [50]. Contrary to our results, D_vein values are higher for Hawaiian Plantago taxa on drier sites [25]. Since D_vein strongly determines water transport capacity [8], [9], epiphytic ferns have distinctly lower leaf hydraulic conductance due to low D_vein than terrestrial ferns. Given that there is a tradeoff between hydraulic capacity and safety [22], epiphytic ferns may have a vascular system that is more resistant to cavitation than terrestrial species [5]. A distinct difference in D_vein and consequent water transport capacity is probably responsible for the significant difference in A_max between terrestrial and epiphytic ferns. These results reflect an obvious differentiation between epiphytic and terrestrial ferns in ecological adaptations to the environmental conditions of their native habitats.

Leaf traits in relation to phylogeny

Among leaf traits examined, only stomatal length (SL) showed a strong phylogenetic conservatism (Table 3). This result is consistent with the notion that SL is related to phylogeny in angiosperms [34]. Previous studies have suggested that SL in Arabidopsis is strongly correlated with genome size, but is independent from environment [51], and that the frequency of polyploidy in ferns (31%) is much higher than angiosperms (15%) [52]. Polyploidy provides a rapid route for species evolution and adaptation [53]. Thus, speciation linking to polyploidy might explain evolutionary shifts associated with genome size and SL in ferns.

Phylogenetic signals for most of the traits examined here were weak, possibly because of a departure from Brownian motion evolution, such as adaptive evolution, that would not have been correlated with phylogeny. This reflects the outcome of selection in heterogeneous environments, allowing species to acclimate to their current growing conditions [54].

Correlation of photosynthesis with water supply

As expected, A_max was positively correlated with D_vein, SD, and g_s, consistent with our hypothesis. Previous studies have suggested that D_vein is correlated with maximum hydraulic conductance and A_max across a wide range of species [7], [16], [17]. Generally, ferns have lower A_max than angiosperms, which are attributable to their much lower D_vein and hydraulic conductance [5], [10], [38]. In contrast, angiosperms have dramatically higher values for D_vein that parallel their higher rates of photosynthesis and transpiration [4], [16]. Feild & Brodribb (2013) found that high vein density evolution is strongly associated with simplification of the perforation plates of primary xylem vessels. Such simple perforation plates associated with high D_vein only occurred in the leaf xylem of derived angiosperm clades, while scalariform perforation plates associated with low D_vein occurred in extant basal angiosperms and ferns [55]. Compared with that of the derived angiosperms (>12 mm mm⁻²) [55], the 30 tropical ferns in our study exhibited very lower D_vein (0.66–1.68 mm mm⁻²). Thus, due to the lower water supply capacities than angiosperms, ferns cannot efficiently replace the water transpired, which consequently results in a high water potential gradient from roots to leaf and prevents the ferns from achieving and maintaining a high leaf water potential, stomatal conductance, and photosynthetic rate during transpiration [7]. This confirmed the hypothesis in angiosperms that vein density evolution enable higher photosynthesis [10], and low stomatal conductance and photosynthesis of ferns could be caused by low vein density.

Correlations among leaf functional traits

Our present results support the hypothesis that stomatal density is closely related to D_vein. We also found that D_vein in Paphiopedilum (Orchidaceae) is evolutionarily correlated with SD [26]. The close correlation between D_vein and SD in ferns and Paphiopedilum support the idea of coordinated development and functioning between leaf veins and stomata [17], which is important for optimizing the photosynthetic yield relative to carbon investment in leaf venation, conserving water loss and maintaining xylem function [6]. However, environments would modify the linkage between D_vein and SD in woody angiosperms [23]. The most efficient balance of vein and stomatal investment occurs when the supply of water to evaporative sites is just enough to maintain stomata fully open in the contrasting environments [23], [37].

Leaf structural traits can affect photosynthesis through changing the diffusion path from stomata to chloroplast or hydraulic resistance [41]. However, our study did not find any significant correlations between A_max and leaf structural traits such as mesophyll thickness (Table S4 in File S1). Leaf water content was positively correlated with thicknesses of the cuticle, upper epidermis, lower epidermis, mesophylls, and the whole-leaf (Figure 5). This demonstrates that leaf structural traits contribute to water conservation. Both leaf thickness and epidermal characteristics affect water status [40]. A thick leaf can store more water and maintain more stable hydraulic functioning during drought periods [42].

Conclusions

Leaf functional traits of 30 tropical ferns examined varied considerably, but only stomatal length was strongly phylogenetically conserved. We note correlated evolution between maximum photosynthetic rate and vein density, and between stomatal density and vein density in ferns. These results indicate that lower water transport capacity limits the photosynthesis of these tropical ferns. These findings provide novel insights into the correlated evolution of traits involving water economy in early vascular plants such as ferns.