Affiliation:
1. New College of Florida 5800 Bay Shore Road Sarasota 34243 FL USA
2. University of Florida 3215 Hull Road Gainesville 32611 FL USA
3. California State University San Marcos 333 South Twin Oaks Valley Road San Marcos 92096 CA USA
4. Kampong of The National Tropical Botanical Garden 4013 South Douglas Road Miami 33133 FL USA
5. Marie Selby Botanical Garden 1534 Mound Street Sarasota 34236 FL USA
6. New York Botanical Garden 2900 Southern Boulevard Bronx 10458 NY USA
Abstract
AbstractPremiseUp to half of tropical forest plant species grow on other plants. Lacking access to soils, vascular epiphytes have unique adaptations for mineral nutrition. Among the most distinctive is the tank growth form of certain large bromeliads, which absorb nutrients that are cycled by complex microbial communities in water trapped among their overlapping leaf bases. However, tanks form only after years of growth by juvenile plants, which must acquire nutrients differently. Understanding how nutrient dynamics change during tank bromeliad development can provide key insights into the role of microorganisms in the maintenance of tropical forest biodiversity.MethodsWe evaluated variations in plant morphology, growth, foliar nitrogen physiology, and phyllosphere bacterial communities along a size gradient spanning the transition to tank formation in the threatened species Tillandsia utriculata.ResultsSequential morphological and growth phases coincided with the transition to tank formation when the longest leaf on plants was between 14 and 19 cm. Before this point, foliar ammonium concentrations were very high, but after, leaf segments absorbed significantly more nitrate. Leaf‐surface bacterial communities tracked ontogenetic changes in plant morphology and nitrogen metabolism, with less‐diverse communities in tankless plants distinguished by a high proportion of taxa implicated in ureolysis, nitrogen fixation, and methanotrophy, whereas nitrate reduction characterized communities on individuals that could form a tank.ConclusionsCoupled changes in plant morphology, physiology, and microbiome function facilitate the transition between alternative nutritional modes in tank bromeliads. Comparing bromeliads across life stages and habitats may illuminate how nitrogen‐use varies across scales.
Reference69 articles.
1. Diversity and putative metabolic function of prokaryotic communities in tank bromeliads along an elevation gradient in tropical Mexico;Aguilar‐Cruz Y.;Frontiers in Microbiology,2022
2. nifH sequences and nitrogen fixation in Type I and Type II methanotrophs;Auman A. J.;Applied and Environmental Microbiology,2001
3. Phenotypic plasticity in Bromelia serra Griseb.: Morphological variations due to plant size and habitats with contrasting light availability;Barberis I. M.;Revista Brasileira de Biociências,2017
4. Juvenile tank‐bromeliads lacking tanks: Do they engage in CAM photosynthesis?;Beltrán J. D.;Photosynthetica,2013
5. The Mineral Nutrition of Epiphytes