Dew can represent an alternate water source in epiphytic bromeliads. However, the physiological relevance of dew to withstand the dry season, within seasonal forests, is not fully understood. To study the effect of dew deposition in the physiological response of four Tillandsia species with contrasting morphologies, we performed an experiment in the tropical dry deciduous forest of Dzibilchaltún, Mexico, during the transition from the wet to the dry season. Half of the individuals were covered every night with a plastic tarp to prevent dew deposition. Environmental variables were monitored, and physiological variables (relative water content, leaf succulence, nocturnal tissue acidification and electron transport rate) were measured at the beginning and end of the experiment. We found that throughout the drought, there was consistent nighttime dew formation for >4 h. Both the time the leaves spent at a temperature below dew point of the air and the effect on water and carbon metabolism was species -specific, as evidenced by the comparison among the exposed and covered (dew -deprived) plants. Tillandsia elongata and Tillandsia brachycaulos had longer times of dew formation and showed higher water content at the end of the experiment when exposed to dew, the latter species also had a significant effect of dew on nocturnal acidity. In contrast, neither Tillandsia yucatana nor Tillandsia fasciculata seemed to be using dew as a relevant source of water during the dry period. We discuss the species’ morphoanatomical traits that may be related to the differences in dew formation and use.
Introduction
Approximately half of the Bromeliaceae are epiphytes, making it the second most important angiosperm family in terms of the number of epiphytic species (Zotz, 2013). In the canopy habitat, epiphytic bromeliads endure periods of drought interspersed by pulses of moisture input (Andrade, 2003; Martin, 1994; Reyes-García, Mejia-Chang, & Griffiths, 2012; Zotz & Hietz, 2001). To cope with these conditions, these species display an array of morphological and physiological traits aimed at acquiring, storing, and conserving water. These include succulent leaves, water impounding “tanks,” and crassulacean acid metabolism (Benzing, 2000; Crayn, Winter, & Smith, 2004; Dodd, Borland, Haslam, Griffiths, & Maxwell, 2002; Martin, 1994). In addition, another important feature is the presence of foliar trichomes, which are highly hygroscopic, scale-like, multicellular structures that absorb water and nutrients (Benzing, 2000; Benzing, Henderson, Kessel, & Sulak, 1976; Givnish et al., 2014).
Epiphytic bromeliad species mainly conform to one of two functional groups: “tank” and “atmospheric” species (Benzing, 1990; Pittendrigh, 1948), which reflect two distinct ecological and physiological strategies. In tropical dry deciduous forests, tank species are rare because their tolerance to drought, once tank water is exhausted, is limited; so these plants show a more conservative use of water (Graham & Andrade, 2004; North, Lynch, Maharaj, Phillips, & Woodside, 2013; Pittendrigh, 1948; Reyes-García, Griffiths, Rincón, & Huante, 2008; Reyes-García et al., 2012; Wolf & Alejandro, 2003). Both tank and atmospheric epiphytic bromeliads from seasonal environments can display succulent leaves with a dense cover of well-developed trichomes (Benzing, 2000). Yet, atmospheric species, which are more common in these dry forests, usually show higher leaf succulence and are better adapted to use water from rain pulses. Also, atmospheric species are capable of maintaining photosynthetic activity under low leaf relative water content (RWC; Benzing, 2000; Cach-Pérez et al., 2013; Lüttge, 1989; Pierce, 2007; Reyes-García et al., 2012).
Apart from rain, epiphytes may rely on dew and fog as alternate sources of water, which influences their abundance, vertical and altitudinal distribution, and survival (Andrade, 2003; Cavelier & Goldstein, 1989; Guevara-Escobar et al., 2011; Rapp & Silman, 2014; Reyes-García et al., 2008). Dew deposition generally occurs during nighttime at high humidity and relatively low temperature. When the air adjacent to the leaves cools down to its dew point, and leaf surfaces get colder than that surrounding air, water will condense on those surfaces (Nobel, 2009).
Fog and dew can be the main source of water in bromeliads from arid environments (González et al., 2011; Pinto, Barría, & Marquet, 2006). However, the relative importance in the total budget of dry forests epiphytes seems to vary greatly between species, location, and season (Andrade, 2003; Graham & Andrade, 2004; Reyes-García et al., 2008, 2012; Wu et al., 2018). The few studies that have explored the importance of dew and fog have found that the ability to access, intercept, and use these water resources may depend on plant morphology and physiology (Graham & Andrade, 2004; Martorell & Ezcurra, 2007; Reyes-García et al., 2012).Yet, the magnitude of the effect of dew deposition on the physiology of epiphytic species in situ remains to be quantified, as the question to its actual relevance in plant survival remains unanswered.
This study evaluated the importance of dew deposition in the physiological response of four epiphytic Tillandsia species with contrasting life forms (from tank to atmospheric) in the tropical dry deciduous forest of Dzibilchaltún, Mexico. A field experiment was setup during the transition from the early dry season, locally known as “nortes” characterized by daily low temperatures, wind events, sparse rainfall, and dew deposition (Andrade, 2003; Orellana, 1999), to the dry season. To do so, we monitored the physiology of the species during this transition, either under natural conditions or under semicontrolled conditions where plants were covered with a plastic tarp during the night to prevent dew formation.
We expected that because of this seasonal transition, the tank species would show a more marked decrease in photosynthetic activity, with more pronounced changes in RWC and leaf succulence than atmospheric species. We also expected that dew-deprived plants would show significantly lower photosynthetic activity and water status values in comparison to the plants exposed to dew deposition.
Materials and Methods
Study Site and Plant Species
This study was conducted at the Dzibilchaltún National Park (21° 05′N, 89° 35′W, 8 m a.s.l.), Yucatan, Mexico, which is characterized as a tropical dry deciduous forest with a mean annual rainfall of 700 mm and mean temperature of 25.8°C (Thien, Bradburn, & Welden, 1982). A marked dry season (March–May) is separated from the wet season (June–October) by an early dry season known locally as “nortes” (November–February). The latter is characterized by scattered rainfall, low nocturnal temperatures (<20°C), and dew formation (Herrera-Silveira, 1995; Orellana, 1999).
Four epiphytic bromeliad species of the genus Tillandsia were selected: the shallow tank Tillandsia elongata Kunth; Tillandsia fasciculata Sw., which is variously described as an atmospheric, a tank or an intermediate species (Bader, Menke, & Zotz, 2009; Cach-Pérez, Andrade, Cetzal-Ix, & Reyes-García, 2016; Cach-Pérez, Andrade, & Reyes-García, 2018; Pittendrigh, 1948; Zotz & Thomas, 1999); Tillandsia brachycaulos Schltdl., an atmospheric generalist with a limited water impounding capacity; and Tillandsia yucatana Baker, an atmospheric with very succulent leaves and no water impoundment. All species are obligate epiphytes with crassulacean acid metabolism and are native to the study site (Cach-Pérez et al., 2013; Ramirez-Morillo, Carnevali, & Chi May, 2004). Species differ strongly in morphology, ecological type, and distribution range along the Yucatan Peninsula (Figure 1 and Table 1). Most of the species are rare at the study site (Cach-Pérez et al., 2013; Chilpa-Galván, Tamayo-Chim, Andrade, & Reyes-García, 2013), a protected area. Thus, apart from T. brachycaulos, which was collected at Dzibilchaltún, plants were collected elsewhere: T. elongata was collected at Homún; T. fasciculata at Hopelchén; and T. yucatana at Komchén, all three sites within the Yucatan Peninsula. Plants, which were adult size, were kept in a shade house at the Centro de Investigación Científica de Yucatán (located <10 km from Dzibilchaltún) for a week before the experiment.
Figure 1.
The epiphytic Tillandsia species with contrasting morphologies and life forms selected for this study. The white bars are 10 cm. Adapted from Tillandsia yucatana by C. Espadas-Manrique, others by E. Chávez-Sahagún.
Table 1.
Life form, water impounding capacity, Leaf Size (Length × Width), Specific Leaf Area (SLA, cm2 g−1) and Habitat on the Yucatán Peninsula for the Species Used in This Experiment.
The experiment was established at a site with abundant epiphytes in December 2015. A group of 12 to 16 individuals per species were mounted on a wire mesh 1.2 m above the ground. The plants were placed evenly spaced in two rows, with the smaller atmospheric species above the larger tank species to prevent shading effects. The plants had been receiving natural rain at the site or nearby shade house and were watered to reduce stress from manipulation when mounted. After 36 days of acclimation (during which no rain was registered at the site), half the plants of each species were covered daily with a plastic tarp during nighttime (18:00 to 06:00 h) to prevent dew deposition on the leaves; the rest of the plants were left uncovered (Supplementary Material). The covered treatment isolated the air to prevent condensation, but encompassed all the plants in the treatment together, thus ensuring a large amount of air within the enclosure so that nighttime gas exchange was not impaired. The experimental treatment lasted 8 weeks from late January to mid-March 2016.
To isolate the effect of dew, leaf wetting from rainfall was minimized. During this period there was only one important rainfall event on March 13 (12.7 mm); to prevent plants from getting wet, all plants, irrespective of treatment, were covered with two plastic tarps before the event started. Minor rainfall events (1–3 mm), occurred during January (five events) and February (one event; data from a CONAGUA meteorological station); however, no measures were taken in such instances.
Microenvironment Measurements
Air temperature and relative humidity were recorded hourly using iButtons (Maxim iButton, Silicon Valley, USA), which were placed at the same height as each group of plants. Vapor pressure deficits were calculated after Jones (1992). Leaf temperature was measured with thermocouples attached to the underside of leaves with microporous tape; temperature was measured every minute and averages recorded every 10 min using a datalogger (CR21X, Campbell Scientific, North Logan, USA). To measure the duration of dew events, two leaf wetness sensors (Model 237 Leaf Wetness Sensor, Campbell Scientific, North Logan, USA) were affixed to the wire mesh along the plants in each treatment, averages recorded every 10 min with the same datalogger.
The dew point of the air (td) was calculated after Lawrence (2005):
where RH is the relative humidity, t is the air temperature, and A1 = 17.625, and B1 = 243.04°C. The theoretical duration of dew deposition was calculated as the time when leaf temperature was ≤ air dew point.
Physiological Data
The effect of dew deposition on plant physiology was assessed by determining nocturnal acidification, RWC, leaf succulence, and electron transport rate (ETR) in late January just before beginning the nightly covered treatment (referred to as early dry season), and in mid-March after the plants had been under the treatment for 8 weeks (referred to as dry season). All physiological measurements were carried out on 5 to 8 young, but fully expanded healthy leaves per species per treatment. To characterize RWC, leaf samples were collected before dawn and placed in a sealed bag with moist tissue paper and transported in a cooler with ice to the laboratory to obtain fresh weight, and then placed in distilled water for 48 h to obtain saturated weight. Leaves were then scanned, and leaf area was estimated using ImageJ software. After drying at 65°C for 48 h, dry weight was determined. RWC was calculated as follows: (fresh weight − dry weight)/(saturated weight − dry weight) × 100; leaf succulence was calculated as ([fresh weight − dry weight] × 1,000)/leaf area. To further characterize relevant traits that may differentiate the species, we measured specific leaf area (SLA) as follows: (leaf area [cm2])/(dry weight [g]), at the beginning of the experiment.
To estimate nocturnal acidification (ΔH+), samples from every plant of each species were collected at sunset and before dawn the next day and frozen in liquid N2 on site. In the laboratory, samples were first weighed and then macerated in a porcelain mortar and boiled in distilled water for 5 min. After cooling to room temperature, samples were titrated with sodium hydroxide (0.01 N NaOH) using an automatic titrator (702 SM Tritino, Metrohm, Switzerland). Acidity at dawn minus acidity at sunset is reported as ΔH+ and expressed in mmol H+ g−1 fresh weight.
Chlorophyll fluorescence was measured in the field with a pulse amplitude-modulated fluorometer (Mini-PAM, Walz Effeltrich, Germany). Light response curves were performed in dark-adapted leaves to assess maximum ETR (ETRmax) values. ETR was calculated after Maxwell & Johnson (2000):
where ΦpsII is the quantum yield of photosystem II, PFDa is absorbed photon flux density, and 0.5 accounts for the partitioning of energy between PSII and PSI. Values of leaf light absorption or absorptance were obtained from the mid-leaf section of recently excised leaves from plants used in this experiment (n = 5) using a ultraviolet/visible/near infrared Lambda 900 spectrometer coupled with a PELA9026 integrating sphere (Perkin-Elmer, MA, USA). Absorptance values (a) used were as follows: T. elongata = 0.72, T. fasciculata = 0.65, T. brachycaulos = 0.67, and T. yucatana = 0.78.
Statistical Analyses
Linear regressions were performed to assess the relationship between average nocturnal relative humidity, air temperature, or vapor pressure deficit, and the days passed from the beginning of the experiment. Repeated measures analyses of variance (ANOVAs) were used to analyze the effect of the season, species, and treatments on the duration of dew deposition, RWC, leaf succulence, nocturnal acidification, and ETRmax. Tukey’s post hoc tests were performed. Differences in SLA between species were analyzed with a nonparametric Kruskal–Wallis test followed by paired comparisons since this particular dataset did not fulfil the assumptions of the ANOVA (Kruskal & Wallis, 1952). Repeated measures ANOVA were performed using STATISTICA v.10 (Statsoft Inc., Tulsa, OK, USA); regressions and Kruskal–Wallis were run using the program SPSS 22 (Chicago, IL, USA). A value of p < .05 was used as the cut-off for significant differences.
Results
Environmental Conditions
During the transition from the early dry to the dry season, nocturnal relative humidity progressively decreased (R2 = .13, p = .02 Figure 2(a)), while both nocturnal temperature (R2 = .53, p < .001; Figure 2(b)) and vapor pressure deficit (R2= .30, p < .01; Figure 2(c)) increased.
Dew Deposition
Leaf temperature measurements indicate that the average dew deposition lasted 04:24 to 05:26 h every night in uncovered plants (Figure 3(a)), with a significant species effect, F(3, 672) = 5.806, p < .001. Dew duration was significantly longer in T. elongata compared with T. yucatana (Tukey’s test, p < .05). The treatment effect was also significant, F(1, 672) = 1047.1, p < .001, as the covered plants had much shorter periods of dew deposition. Among covered plants, dew formation lasted only 00:20 to 01:02 h (Figure 3(a)) and species differences were not significant. The leaf wetness sensors gave similar results with an average of dew deposition duration of 08:01 h in the exposed, and 01:09 h for the covered treatments (Figure 3(b)). Leaf temperature showed a sharp decrease between 18:00 and 06:00 h, while dew point of the air showed a more gradual decrease in both treatments (Figure 4). Dew point of the air was lower within the plastic tarp of the covered treatment (Figure 4), which caused plants in this treatment to reach the dew point for much shorter periods.
Specific Leaf Area
Pairwise comparisons found species differences among in SLA (H [3, N = 58] = 47.18; p < .001; Table 1). T. elongata and T. brachycaulos had the highest values (99.5 and 106.3 cm2 g−1, respectively), followed by T. fasciculata and T. yucatana that showed the lowest SLA values (48.4 and 36.2 cm−2 g−1, respectively).
Water Relations
Progression of the dry season and the exposure to dew treatments affected the water relations of the four species differently (Figure 5). T. yucatana showed the largest drop in RWC between the early dry and dry season (mean decrease of 30% from its original values, Tukey p < .05; Figure 5(a) and (b)), but this species was not affected by the nightly covered treatment. T. fasciculata had the smallest reduction in RWC in both treatments (mean reduction of 8.5%; Figure 5(a) and (b)), and differences were non-significant; this species was not affected by treatment either. In the case of T. elongata and T. brachycaulos, reduction of RWC between early dry and dry season was only significant in covered plants (Tukey, p < .05), with a 26% and 30% decrease, respectively (Figure 5(b)), compared to the plants exposed to dew (5% and 11% decrease, respectively; p > .05, Figure 5(a)).
Figure 5.
Water relations at the beginning (early dry season: All plants exposed to rain and dew) and at the end (dry season: half of the plants dew deprived) of the 8-week long experiment, for leaves of T. elongata, T. fasciculata, T. brachycaulos, and T. yucatana in the exposed (open bars) and covered treatments (shaded bars), (a) RWC for exposed plants, (b) RWC for covered plants, (c) leaf succulence for exposed plants, and (d) leaf succulence for covered plants. Data are means ± SE (n = 6–8). Asterisks indicate significant differences between seasons for each species and treatment. RWC = relative water content.
Overall, there were species differences in succulence, with T. elongata having the least succulent leaves (mean value of 43.8 mg H2O cm−2 at the beginning of the experiment) and T. yucatana having the most succulent leaves (initially 191.8 mg H2O cm−2, p < .001). However, only T. yucatana showed significant changes in succulence, with a reduction of approximately 50% during of the dry season (Tukey p < .0001); in the overall ANOVA, there was a significant Species × Time interaction; F(3, 50) = 47.15, p < .0001. The other three species showed a nonsignificant tendency to lower succulence as the drought progressed. Covering did not affect succulence in any of the species significantly.
Carbon Metabolism
Overall, the species had differences in nocturnal acidification, with T. fasciculata and T. brachycaulos reaching higher values than T. yucatana (Tukey, species effect p < .05). With the onset of the dry season, there was a tendency toward reduced nocturnal carbon uptake (measured as tissue acidification) (Figure 6(a) and (b)), with different species responses to the nightly covered treatment, Time × Species × Treatment interaction, F(3, 46) = 3.74, p < .05. Nocturnal acidification in dew-deprived T. brachycaulos plants was reduced by >50% with the progressing dry season (Tukey p < .05). In comparison, exposed plants had a nonsignificant reduction of ∼27%. T. elongata did not show significant changes but had the same tendency as T. brachycaulos with a larger decrease in acidification in covered than exposed plants. T. fasciculata showed the opposite trend with a significant reduction in tissue acidification (∼47%, Tukey p < .05) only found in exposed plants, with no significant change in covered plants. T. yucatana showed no significant change related to season or treatment, although there was a large nonsignificant reduction in acidity (∼50%) with the onset of the dry season.
Figure 6.
Nocturnal acidification (ΔH+) and maximum electron transport rate (ETRmax) at the beginning (early dry season: All plants exposed to rain and dew) and at the end (dry season: half of the plants dew deprived) of the 8-week long experiment, for leaves of T. elongata, T. fasciculata, T. brachycaulos, and T. yucatana in the exposed (open bars) and covered treatments (shaded bars). (a) ΔH+ for exposed plants, (b) ΔH+ for covered plants, (c) ETRmax for exposed plants, and (d) ETRmax for covered plants. Data are means ± SE (n = 6–8 for ΔH+, and n = 5 for ETRmax). Asterisks indicate significant differences between seasons for each species and treatment.
Contrary to our expectations, there was a tendency to increase ETRmax values from the early dry to dry season (Figure 6(b) and (c)). However, this increase was significant only for T. yucatana, which also had the highest values at the end of the experiment, ∼60% increase, Tukey p < .01, overall ANOVA significant Species × Time interaction; F(3, 30) = 6.32 p < .0001. The covered treatment did not have a significant effect on any of the species.
Discussion
As expected, during the transition from early dry to dry season, the canopy microenvironment showed a progressive nighttime increase in air temperature and decrease in air humidity (Figure 2). Despite the lack of rainfall, nighttime dew formation was consistently recorded for several hours both on the leaves of the epiphytic Bromeliaceae and on the leaf wetness sensors (Figures 3 and 4). There were, however, differences among bromeliad species in both the amount of dew condensed in its leaves and the influence of that water source on plant water status and carbon metabolism.
Our data evidence a gradient of dew formation among the species, with the leaves of T. elongata staying under the dew point of the air during a longer period every night, in comparison to the species with the shortest period, T. yucatana (Figures 3 and 4). In several ways, these two species represent contrasting morphological strategies, which may influence their capacity for dew condensation. The less succulent leaves of T. elongata lose more heat to the environment and thus get cooler (Andrade, 2003), promoting leaf temperature to drop below the dew point faster during the night. In contrast, T. yucatana had the most succulent leaves, which represent important water reserves for this species that is abundant at sites with very low annual rainfall (Cach-Pérez et al., 2013). The high thermal capacity of water means that the succulent leaves will take longer to cool during the night (Griffiths & Males, 2017), reducing dew deposition. Flat surfaces found in the wide leaves with horizontal angles of the tank species, T. elongata, also promote dew condensation (Kidron, 2005); while the tubular, twisted leaves of the atmospheric T. yucatana lack these surfaces. Leaf morphology also evidences that T. elongata has higher leaf surface per unit weight than T. yucatana (SLA; Table 1), again increasing the surface exposed for dew formation and absorption in the former species. Finally, the water absorbing leaf trichomes may obstruct dew formation, since water droplets form on the exposed cooler leaf cuticle (Pierce, 2007). Trichome size and density are variable among the Tillandsia species studied, with T. elongata having the lowest density and smaller trichome size and T. yucatana having higher density and larger trichomes (Cach-Pérez et al., 2016). Together, leaf succulence, shape, angle, and trichome cover contribute to longer dew condensation time in T. elongata and a shorter time in T. yucatana. the The other two Tillandsia species have intermediate values of these morphological variables and show intermediate duration of dew formation.
Experimental data have shown that fog (or dew) might not be enough to support growth or recover high RWC in epiphytic bromeliads from a tropical dry deciduous forest after a drought treatment (Reyes-García et al., 2012). However, we hypothesized that it could contribute to delay the effects of the dry season by maintaining favourable water status and allowing some carbon uptake. Our results support this hypothesis for those species with leaves showing longer hours below dew point. T. elongata and T. brachycaulos did not suffer significant water loss from the early dry to the dry season when exposed to dew but lowered their RWC 26% to 30% under the dew deprived treatment (Figure 5). The effect of the conserved water status was evident on carbon metabolism in T. brachycaulos, showing a consistent pattern of maintained nocturnal acidity values under dew–exposure, but reduced acidity when dew deprived (Figure 6). The same nonsignificant pattern was observed in T. elongata.
Overall, T. fasciculata seemed unaffected by the seasonal drought or the dew deprivation treatment; this species did not show changes in any of the water (Figure 5) or carbon use (Figure 6) parameters measured. T. fasciculata was the largest sized of the species used in this study (Table 1), and this confers more area to store water and in general a higher capacity to withstand stress (Zotz, Hietz, & Schmidt, 2001). Its thick leaves (SLA; Table 1) provide a lower ratio of plant leaf area to plant water content, allowing the species to maintain stomata open during the drought, but with a relatively low loss in internal water content (Zotz & Andrade, 1998). The high nocturnal acidification observed (Figure 6) could also be related to high water use efficiency in this species. Thus, a more intense or longer drought would be needed to evaluate whether dew is being used by T. fasciculata.
The unexpected increase in ETRmax during the experiment in all species (Figure 6) partly reflects an increase in incident light as the trees begin to lose their leaves in response to drought, increasing approximately 30% (from 14 to 21 mol m−2 d−1, data not shown). Yet, the increase in ETR was unaccompanied by a similar increase in carbon uptake measured as nocturnal acid accumulation; this phenomenon, observed in bromeliads, has been assumed to reflect photorespiration and to be important for photoprotection (Maxwell, 2002; Rosado-Calderón et al., 2018). This excess (presumably photorespiratory) ETR has been shown to be higher in phenotypes previously adapted to drier conditions than those grown under milder environments (Rosado-Calderón et al., 2018). The high ETR shown in T. yucatana may relate to its success in the driest sites of the peninsula, such as mangroves and coastal scrubs (Cach-Pérez et al., 2013), where the need to dissipate excess energy may be large.
In summary, while nocturnal dew can be an important source of water for epiphytic bromeliads in the deciduous forest of Dzibilchaltún during the transition from the early dry to the dry season, its importance varies among species, and the access to this secondary water source may depend on morphology.
Implications for Conservation
Epiphytes are highly sensitive to changes in the environment, this makes them particularly vulnerable to climate change (Cach-Pérez, Andrade, & Reyes-García, 2014; Wagner & Zotz, 2018), which also makes them possible early indicators of the effects of climate change on forests (Cach-Pérez et al., 2014, 2018). Since the formation of dew is closely related to the minimum daily temperature, increasing temperatures as a consequence of climate change may negatively affect its availability in the future. In the case of the Yucatán Peninsula, more intense dry seasons and higher temperatures are expected to be more frequent with climate change (Orellana, Espadas, Conde, & Gay, 2009). Changes in the dew deposition regime could be followed by monitoring yearly changes in the RWC during the early dry season, especially in species like T. brachycaulos and T. elongata. Here, we show that while dew may not be a source of water as important as rain, it is still a valuable one and its scarcity may have a negative effect on the survival of sensitive species.
Supplemental Material
Supplemental material for Dew Can Prolong Photosynthesis and Water Status During Drought in Some Epiphytic Bromeliads From a Seasonally Dry Tropical Forest
Supplemental Material for Dew Can Prolong Photosynthesis and Water Status During Drought in Some Epiphytic Bromeliads From a Seasonally Dry Tropical Forest by Eduardo Chávez-Sahagún, José Luis Andrade, Gerhard Zotz and Casandra Reyes-García in Tropical Conservation Science
Acknowledgments
The authors thank Roberth Us, Celene Espadas, Manuela Tamayo, Susana Dzib, and Harry Moreno for field and laboratory assistance. The authors also thank Dzibilchaltún National Park-INAH.
Declaration of Conflicting Interests
The author(s) declared no potential conflicts of interest with respect to the research, authorship, and/or publication of this article.
Funding
The author(s) disclosed receipt of the following financial support for the research, authorship, and/or publication of this article: Eduardo Chávez-Sahagún received a scholarship from CONACYT 419242, the study was funded by SEP-CONACYT project 221490 and INEGI-CONACYT project 290916.
