Tropical Bromeliads Research Articles

Environmental predictors affect α- and β-diversity of tropical bromeliad macroinvertebrates

We tested the hypothesis that abiotic predictors, both influence α and β-diversity of macroinvertebrate communities in the phytotelmata of the terrestrial bromeliad, Vriesea philippocoburgii. Macroinvertebrates were sampled in 58 bromeliads in a restinga in Brazil and estimated both the α and β-diversity in each bromeliad, and then partitioning them into nestedness and turnover. We then used Generalized Linear Models and partial Mantel tests to identify which environmental factors predict these diversity components for the macroinvertebrate communities. The size of the plant positively influenced α-diversity, whereas light intensity strongly influenced β-diversity. Both components were influenced by organic matter. Plants exhibiting large differences in values of organic matter and light intensity had different macroinvertebrate communities. Furthermore, bromeliad systems exhibit high β-diversity values governed by turnover. Our findings demonstrate the importance of considering α and β-diversities in studies that assess the diversity patterns of aquatic macroinvertebrates and suggest that environmental changes that modify the structure of aquatic macroinvertebrate communities could have impacts on ecosystem processes.

Effects of warming on the structure of aquatic communities in tropical bromeliad microecosystems.

Freshwaters are among the most vulnerable ecosystems to climate warming, with projected temperature increases over the coming decades leading to significant losses of aquatic biodiversity. Experimental studies that directly warm entire natural ecosystems in the tropics are needed, for understanding the disturbances on aquatic communities. Therefore, we conducted an experiment to test the impacts of predicted future warming on density, alpha diversity, and beta diversity of freshwater aquatic communities, inhabiting natural microecosystems-Neotropical tank bromeliads. Aquatic communities within the tanks bromeliads were experimentally exposed to warming, with temperatures ranging from 23.58 to 31.72°C. Linear regression analysis was used to test the impacts of warming. Next, distance-based redundancy analysis was performed to assess how warming might alter total beta diversity and its components. This experiment was conducted across a gradient of habitat size (bromeliad water volume) and availability of detrital basal resources. A combination of the highest detritus biomass and higher experimental temperatures resulted in the greatest density of flagellates. However, the density of flagellates declined in bromeliads with higher water volume and lower detritus biomass. Moreover, the combination of the highest water volume and high temperature reduced density of copepods. Finally, warming changed microfauna species composition, mostly through species substitution (β repl component of total beta-diversity). These findings indicate that warming strongly structures freshwater communities by reducing or increasing densities of different aquatic communities groups. It also enhances beta-diversity, and many of these effects are modulated by habitat size or detrital resources.

Illuminating protist diversity in pitcher plants and bromeliad tanks.

Many species of plants have evolved structures called phytotelmata that store water and trap detritus and prey. These structures house diverse communities of organisms, the inquiline microbiome, that aids breakdown of litter and prey. The invertebrate and bacterial food webs in these systems are well characterized, but less is known about microbial eukaryotic community dynamics. In this study we focus on microbes in the SAR clade (Stramenopila, Alveolata, Rhizaria) inhabiting phytotelmata. Using small subunit rDNA amplicon sequencing from repeated temporal and geographic samples of wild and cultivated plants across the Northeast U.S.A., we demonstrate that communities are variable within and between host plant type. Across habitats, communities from tropical bromeliads grown in a single room of a greenhouse were nearly as heterogeneous as wild pitcher plants spread across hundreds of kilometers. At the scale of pitcher plants in a single bog, analyses of samples from three time points suggest that seasonality is a major driver of protist community structure, with variable spring communities transitioning to more homogeneous communities that resemble the surrounding habitat. Our results indicate that protist communities in phytotelmata are variable, likely due to stochastic founder events and colonization/competition dynamics, leading to tremendous heterogeneity in inquiline microeukaryotic communities.

Stem elongation of ornamental bromeliad in tissue culture depends on the temperature even in the presence of gibberellic acid

Acanthostachys strobilacea Link, Klotzsch, & Otto is an ornamental bromeliad native to Brazilian Atlantic Forest that naturally exhibits a rosette growth pattern. According to the temperature conditions of the in vitro culture, this species can exhibit stem elongation, facilitating the isolation of the nodal segments to be applied in its micropropagation. The rosette morphology is reestablished when this species is maintained under low temperature, thus allowing the maintenance of a germplasm collection (slow growth storage). Gibberellins (GA) are usually applied to stimulate stem elongation in micropropagated plants. Thus, our aim here was to verify the influence of temperature over the stem elongation of A. strobilacea when GA3 is applied to the medium, thus estimating the use of this phytoregulator in slow growth cultures at low temperatures. Physiological and anatomical studies were performed on plants obtained from nodal segments maintained at 10, 15, 20, and 25 °C. Regardless of the applied treatment, no segments developed at 10 °C. Stem elongation occurred at 25 and 30 °C, and was not seen for plants grown under 15 and 20 °C. The application of 50 µM of GA3 restored stem elongation in plants at 20 but not at 15 °C. The influence of gibberellins on stem elongation of this tropical bromeliad depends on the cultivation temperature, in which low temperature preponderates over the stem elongation effects of GA3. In addition, the optimum temperature for the slow growth of this species depends on the starting temperature of the explant used in the micropropagation.

Environmental control of the microfaunal community structure in tropical bromeliads.

Ecological communities hosted within phytotelmata (plant compartments filled with water) provide an excellent opportunity to test ecological theory and to advance our understanding of how local and global environmental changes affect ecosystems. However, insights from bromeliad phytotelmata communities are currently limited by scarce accounts of microfauna assemblages, even though these assemblages are critical in transferring, recycling, and releasing nutrients in these model ecosystems. Here, we analyzed natural microfaunal communities in leaf compartments of 43 bromeliads to identify the key environmental filters underlying their community structures. We found that microfaunal community richness and abundance were negatively related to canopy openness and vertical height above the ground. These associations were primarily driven by the composition of amoebae and flagellate assemblages and indicate the importance of bottom‐up control of microfauna in bromeliads. Taxonomic richness of all functional groups followed a unimodal relationship with water temperature, peaking at 23–25°C and declining below and above this relatively narrow thermal range. This suggests that relatively small changes in water temperature under expected future climate warming may alter taxonomic richness and ecological structure of these communities. Our findings improve the understanding of this unstudied but crucial component of bromeliad ecosystems and reveal important environmental filters that likely contribute to overall bromeliad community structure and function.

Microbial community ecology: Function over phylogeny.

Analysis of bacterial communities inhabiting water ‘tanks’ in the foliage of tropical bromeliads reveals a surprising similarity in their metabolic capacity, despite large variation in microbial taxa.

Predation Threat Alters Composition and Functioning of Bromeliad Ecosystems

Predators can have dramatic effects on food web structure and ecosystem processes. However, the total effect of predators will be a combination of prey removal due to consumption and non-consumptive effects (NCEs) mediated through changes to prey behavioral, morphological, or life history traits induced to reduce predation risk. In this study, we examined how consumptive and NCEs alter community composition and ecosystem function using the aquatic ecosystem housed within tropical bromeliads. We allowed the recolonization of emptied bromeliads containing either no predators, caged predators (NCEs only), or uncaged predators (NCEs and consumptive effects) and recorded densities of all macro-invertebrates, microbial densities, and in situ CO2 concentrations after 30 days. We found that predators altered community composition and CO2 concentrations largely through NCEs. The magnitude of the effects of NCEs was substantial, contributing more than 50% of the total effects of predators on macro-invertebrate communities. The NCEs of predators were also strong enough to generate a trophic cascade, which significantly increased micro-organisms and ecosystem respiration, which led to increased in situ CO2 concentrations. The most likely mechanism behind the NCEs on macro-invertebrate density was detection of predator cues by ovipositing adult females, who actively choose to avoid bromeliads containing predators. Through this mechanism, predator NCEs modified community colonization, the structure of food webs, populations of lower trophic levels, and ecosystem processes performed by the community. We therefore propose that quantification of the relative strength of predator NCEs in natural ecosystems is critical for predicting the consequences of predator loss from the world’s ecosystems.

Transcriptomics in the tropics: Total RNA-based profiling of Costa Rican bromeliad-associated communities

RNA-Seq was used to examine the microbial, eukaryotic, and viral communities in water catchments (‘tanks’) formed by tropical bromeliads from Costa Rica. In total, transcripts with taxonomic affiliation to a wide array of bacteria, archaea, and eukaryotes, were observed, as well as RNA-viruses that appeared related to the specific presence of eukaryotes. Bacteria from 25 phyla appeared to comprise the majority of transcripts in one tank (Wg24), compared to only 14 phyla in the other (Wg25). Conversely, eukaryotes from only 16 classes comprised the majority of transcripts in Wg24, compared to 24 classes in the Wg25, revealing a greater eukaryote diversity in the latter. Given that these bromeliads had tanks of similar size (i.e. vertical oxygen gradient), and were neighboring with presumed similar light regime and acquisition of leaf litter through-fall, it is possible that pH was the factor governing these differences in bacterial and eukaryotic communities (Wg24 had a tank pH of 3.6 and Wg25 had a tank pH of 6.2). Archaeal diversity was similar in both tanks, represented by 7 orders, with the exception of Methanocellales transcripts uniquely recovered from Wg25. Based on measures of FPKG (fragments mapped per kilobase of gene length), genes involved in methanogenesis, in addition to a spirochaete flagellin gene, were among those most highly expressed in Wg25. Conversely, aldehyde dehydrogenase and monosaccharide-binding protein were among genes most highly expressed in Wg24. The ability to observe specific presence of insect, plant, and fungi-associated RNA-viruses was unexpected. As with other techniques, there are inherent biases in the use of RNA-Seq, however, these data suggest the possibility of understanding the entire community, including ecological interactions, via simultaneous analysis of microbial, eukaryotic, and viral transcripts.

Research Trails Affect the Abundance of an Epiphytic Tropical Bromeliad

AbstractConcerns have been expressed that research methods and research infrastructure may affect the systems under study, which could lead to biased results. Effects of research activities on seedlings, saplings, and understory plants that are subjected to trampling and injury have been demonstrated. However, as of yet, no effects on epiphytic plants have been reported. In this paper, we demonstrate the impact of research trails on the abundance of an epiphytic tropical bromeliad, Guzmania vittata, at a research site in Peruvian Amazonia. Compared to the interior of the forest, the abundance of this bromeliad is significantly higher along the research trails. While we do not know the exact cause for the increased bromeliad abundance along the trails, we discuss enhanced dispersal of anemochorous seeds as a potential mechanism that generates this impact.

Biochemical and anatomical responses related to the in vitro survival of the tropical bromeliad Nidularium minutum to low temperatures

Nidularium minutum is a tropical bromeliad that grows in natural environment with temperatures ranging from 2 to 30 °C. In the present work we cultivated this species in vitro at 5, 10, 15, and 25 °C for 3 and 6 months aiming at assessing biochemical and morphological responses that allow its survival under low temperatures. No survival was observed for plants cultured constantly at 5 °C and the lowest biometric parameters were found for those grown at 10 °C. A thick aquiferous parenchyma, accumulation of reducing sugars, and increased pectin content in the cell walls were observed in plants grown at 10 and 15 °C when compared to those maintained at 25 °C. In plants cultured at 10 °C, leaf bleaching correlated with low chlorophyll content and lower survival rate after 6 months when compared to those grown at 15 °C. The best in vitro culture condition for slow growth and plant acclimatization was found to be at 15 °C. This probably correlated with the immediate availability of carbon to restore growth during acclimatization and also with higher root initiation under this condition. This study brings information about the responses related to functional adaptation to low temperatures in N. minutum cultured in vitro that can also be implicated in its survival under natural conditions. Additionally, it suggests the best temperature to form a minimal growth collection to be used in restocking and conservation programs for endangered tropical bromeliads.

Nitrogen isotope ratios shift with plant size in tropical bromeliads.

We describe an ontogenetic shift in nitrogen (N) isotopic values in two rosette-forming epiphytic bromeliads. Leaf tissue N isotope values of small individuals of two bromeliad species (mean -6.2 per thousand ) differed from those of large individuals within each species (mean -0.5 per thousand ). Using references for potential N sources, we calculated the relative contribution of autochthonous (soil-derived through leaf litter) and allochthonous (atmospheric deposition) N with a two-member mixing model. Atmospheric sources contributed as much as 77-80% of the N in small individuals, whereas soil-derived N contributed 64-72% (conservative reference value) to 100% (less conservative reference value) of leaf tissue N in large plants. Shifts in N source with increasing plant size may be important aspects of rainforest complexity, an understudied aspect of ecosystem diversity.