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Bladder function in Utricularia purpurea (Lentibulariaceae): is carnivory important?¹

⁰ Department of Biological Sciences, Florida International University, Miami, Florida 33199 USA

Received for publication September 21, 1999. Accepted for publication March 28, 2000.

	ABSTRACT

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION LITERATURE CITED

 
Utricularia purpurea is a rootless, free-floating, aquatic, carnivorous plant. I quantified biomass investment in U. purpurea traps and determined when traps begin to function and what they trap in natural habitats. In the Everglades of south Florida, plants invest an average of 26% of their biomass in bladders, although bladder number varies among sites and over time. Leaves begin trapping as they mature, and on leaves one whorl older than the most recently matured leaves, almost 100% of bladders have allochthonous material. Despite the substantial investment in their biomass, bladders capture few aquatic microinvertebrates. Almost all mature bladders, however, have living communities of algae, zooplankton, and associated debris. These results support the hypotheses that the important association in U. purpurea bladders is a mutualism rather than a predator–prey interaction and that the major benefit to the plants from bladders is derived from this community.

Key Words: bladderworts • Lentibulariaceae • periphyton • plant carnivory • plant nutrients • trapping rates • Utricularia • Utricularia purpurea

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION LITERATURE CITED

 
The morphological and physiological adaptations of carnivorous plants are among the most complex in the plant kingdom (Juniper, Robins, and Joel, 1989 ). The complexity of these adaptations encourages hypotheses about function on the basis of structures. A critical evaluation of function, however, requires quantification of the numbers and types of prey captured in natural environments, as well analysis of the prey's contribution to the plant's nutrient budget. The number of prey captured by Drosera and Pinguicula species under natural conditions has been reported (Karlsson et al., 1987 ; Thum, 1988 ; Zamora, 1995 ), but comparable data are lacking for Utricularia, the most species-rich genus of carnivorous plants.

Carnivorous plants are defined as plants that (1) absorb nutrients from dead animals next to their surfaces and thus obtain increased fitness and (2) have some morphological, physiological, or behavioral feature to attract, capture, and/or digest prey (Givnish, 1989 ; Juniper, Robins, and Joel, 1989 ). The carnivorous habit has arisen independently at least six times (Albert, Williams, and Chase, 1992 ). Forty-two percentage of the species classified as carnivorous occur in Utricularia (Juniper, Robins, and Joel, 1989 ), and Utricularia has the widest geographical distribution of any carnivorous genus, with species found worldwide from the tropics to arctic regions (Taylor, 1989 ). Habit varies in the genus, including free-floating and affixed aquatics (27%), lithophytes and epiphytes (13%), and terrestrial species that grow in seasonally wet or moist environments (60%) (Taylor, 1989 ). Members of the genus are rootless and have small bladders that can trap allochthonous material. Each bladder has a door that flexes inward. Internal glands in the bladders pump water out, so that "set" traps are under tension with the door lodged against a lip of cells. Mechanical stimulation causes the bladder door to flex open, allowing water and material to be sucked into the bladder.

A cost-benefit model for the evolution of carnivory in plants predicts that carnivory will evolve in sunny, moist, nutrient-poor environments (Givnish, 1989 ). This description typifies Utricularia habitats in the Everglades of south Florida. Several recent studies of Utricularia have examined the costs of carnivory, measuring investment in carnivory as investment in bladders, quantified as bladder number, size, and/or biomass (Friday, 1991, 1992 ; Knight and Frost, 1991 ; Knight, 1992 ). Bladders are known to trap small aquatic animal prey, such as rotifers, copepods, ostracods, cladocerans, and chironomids (Friday, 1989 ; Knight and Frost, 1991 ), and they absorb N and P from these prey (Friday and Quarmby, 1994 ). Thus, in Utricularia species the benefit for investing in bladders is assumed to be nutrients derived from trapping and digesting aquatic organisms. Studies of Utricularia that quantify trapping rates and prey in natural environments, however, are limited. This study quantifies investment in bladders and natural trapping rates in Utricularia purpurea growing in the Everglades of south Florida. In order to understand plasticity in investment in carnivory, it also examines morphological variation in this species.

Terminology
Although the morphological homology of the trap-bearing structures in U. purpurea has been debated (Rutishauser and Sattler, 1989 ; Taylor, 1989 ), here they are referred to as leaves. These leaves occur in whorls along the stem, are subdivided into photosynthetic filaments (the "capillary filaments" of Taylor, 1989 ) and bear bladders at their tips (Fig. 1). The time between the initiation of successive leaf whorls is referred to as a plastochron, a developmentally defined unit of time (Erickson and Michelini, 1957; Larson and Isebrands, 1971).

View larger version (27K): [in this window] [in a new window]   Fig. 1. A diagram of Utricularia purpurea vegetative morphology; brackets and curved lines delimit morphological units that were measured (bracket) or counted (curved line). (A) Whole plant; bladders are shown only at the end of each leaf, but they can be borne at the tips of all leaf filaments. (B) Individual leaf from a leaf whorl; four whorls of photosynthetic filaments (1–4) are illustrated; these filaments can have two additional orders of branching.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION LITERATURE CITED

Methods
Morphological measurements and biomass allocation
Plants for morphological measurements, bladder content data, and biomass allocation studies were collected during the wet season, which occurs from May to October in south Florida. Plants from site A were collected on 23 October and 28 October 1998, from site B on 13 July and 22 July 1998, and from site C on 22 July 1998. Plants from sites B and C were also processed for biomass allocation data; the material for biomass allocation from site A was lost, so an additional collection from site A was made during the dry season on 21 March 1999. Plastic collecting bags were submerged and filled with water, and plants were then moved gently from the water column into the bags, so they were not exposed to air during collection. Plants were brought back to the laboratory, refrigerated, and processed within 4 d of collection.

Similar morphological data were taken on all plants. Traits measured were internode length and diameter, leaf number per whorl, leaf length, number of primary photosynthetic whorls per leaf, and bladder number. For morphological data a single leaf was measured per node from the two most recently matured nodes per plant. For biomass allocation studies, three leaves from the most recently matured node were measured.

Since each whorl of leaves is a developmental unit and the plant then consists of units that are produced at the apex and sloughed off at the base, I analyzed biomass investment in trapping on the basis of investment in a nodal unit, equal to the whorl of leaves and the subtending internode. The first mature nodal unit of plants was removed. Internode length and leaf length were measured with a ruler to the nearest millimetre (Fig. 1). Internode diameter was measured with electronic digital calipers (MAX-CAL, Fowler Co., Inc., Newton, Massachusetts, USA). Leaf number per node and number of whorls of primary photosynthetic filaments per leaf were counted on three leaves at the node. On each of these three leaves, bladders were counted, removed, and dried in an 80°C oven to constant mass. Each leaf minus its bladders was dried separately, as was the subtending internode. These parts were weighed on a microbalance (Mettler Toledo AB54, Mettler Toledo Inc., Westerville, Ohio, USA). Percentage investment in bladders and support structures was calculated from these data. Biomasses of leaves and bladders per leaf for a whorl were averaged and multiplied by the number of leaves per whorl to obtain biomass per leaf whorl. This was added to the dry mass of the subtending internode to determine biomass per nodal unit, and relative biomass allocations to bladders, leaves, and stem (internode) were calculated.

Growth-rate determinations
Growth rates were determined for free-floating plants; initial measurements indicated that plants in mats had much slower growth rates than those reported here. I marked 12–15 plants at four permanent quadrats at each flume site. The free end of a string tied to a styrofoam packing peanut was tied above the most recently matured node of an individual U. purpurea plant. This node was defined based on internode length, leaf length, amount of leaf reflexion, and bladder expansion. The floating styrofoam peanut enabled me to relocate marked plants after several weeks of growth in situ. Plants grew for 4–6 wk, and then the number of mature nodes above the marked node was counted. New plants were marked and followed for every sampling date. Growth was measured every 2–4 mo from October 1997 to November 1998.

Leaf development and bladder contents
Plants used for morphological measurements from sites A, B, and C were analyzed for bladder contents. Leaf whorls were numbered based on relative developmental stage. The most recently matured leaf whorl, as determined by morphological criteria (see description above), was designated as 0. Older leaf whorls were numbered positively, and younger whorls numbered negatively from the 0 whorl. For developmental and bladder content analysis, a single leaf was sampled from each node beginning with node 1 and sampling toward the apex to the -3 to -4 whorl. Leaf length and length of the subtending internode were measured for each whorl, while leaf number and the number of whorls of leaf subdivisions were counted. Bladder number was also counted for all but the youngest leaves. Twenty bladders from each leaf were examined under a Leitz Dialux 20 compound light microscope. Bladders were analyzed by focusing down through the bladder and recording presence or absence of allochthonous material. The bladder walls are a single cell thick and relatively transparent, as illustrated in Figs. 7 and 9, which were taken through bladder walls, and as can be seen in Figs. 5, 6, and 8, which show dark contents through transparent bladder walls. Internal and external walls of bladders were identified by the different types of glands present on the inside and outside of bladders (Juniper, Robins, and Joel, 1989 ; Taylor, 1989 ). The types of multicellular invertebrates present per bladder were quantified for samples from sites A and C.

View larger version (159K): [in this window] [in a new window]   Figs. 3–9. Utricularia purpurea leaves and bladders. 3. Portion of a leaf photosynthetic filament. 4. Bladder from -2 leaf. 5. Bladder from -1 leaf. 6. Bladder from 0 leaf. 7. Interior of bladder in Fig. 6 ; arrow points to a green alga. 8. Bladder from +1 leaf. 9. Interior of bladder in Fig. 8 ; arrows point to living algae (desmids and diatoms). Bar = 20 µm in Figs. 3, 4, 7, 9 ; bar = 100 µm in Figs. 5, 6, 8 . D = bladder door; H = hairs on bladder door; P = photosynthetic epidermis

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION LITERATURE CITED

 
Morphology
Free-floating individuals of U. purpurea are 0.5 m in total length in Shark River Slough. The plants produce whorls of leaves as they grow at the tip and rot at the base (Fig. 1). Every second node can produce a branch bud and an inflorescence bud. Inflorescences grow above the water and produce one or two flowers (Fig. 1; for additional details of development, see Rutishauser and Sattler, 1989 ). Internodes of plants used for the bladder content study averaged 29 mm in length and 1.1 mm in diameter (Table 1). A typical plant in Shark River Slough tends to produce five leaves per whorl (Table 1; 63% of nodes had five leaves, 34% had six leaves, and 3% had four leaves). Each leaf produced whorls of four or fewer photosynthetic filaments, which could themselves be subdivided (Figs. 1B, 3). Most Shark River Slough plants had five of these whorls per leaf (Table 1; 65% had five whorls, 27% had four whorls, and 8% had six whorls). Individual leaf length averaged 39 mm (Table 1). Bladders of U. purpurea are borne at the tips of all orders of leaf filaments.

Neither internode diameter nor leaf length varied significantly among sites, and plants had similar numbers of leaves per nodal whorl and similar numbers of whorls of photosynthetic filaments per leaf (Table 1). Plants did differ significantly among sites with respect to internode length and the number of bladders. In general, plants at sites A and B tended to resemble each other and to differ from plants at site C. Plants at site C produced more bladders per leaf and node than plants at the other two sites (Table 1).

Plants at site A that were collected in the wet season and the dry season were not significantly different in leaf length (40 ± 9 mm in October 1998, vs. 44 ± 8 mm in March 1999) but did differ significantly in bladder number (55 ± 31 bladders per leaf in October 1999 vs. 87 ± 34 bladders per leaf in March 1999).

Investment in bladders
Individual leaves in a whorl produced an average of 74 bladders per leaf (Table 2). Given an average of five leaves per whorl, each whorl was estimated to have 370 bladders.

Leaf and internode dry masses did not vary significantly among sites, but bladder dry mass per leaf and individual bladder biomass did (Table 2). Plants at site C produced significantly more bladders per leaf than those at site B during the wet season. The dry-season plants from site A were similar to wet-season site C plants in their investment in bladders and differed significantly from wet-season site B plants (Table 2). Bladder number was negatively correlated with individual bladder biomass, so that plants with more bladders tended to have lighter bladders, although the correlation was not strong (R² = 0.09, P = 0.0052, N = 86).

Trapping efficiency
Bladders on very young leaves of U. purpurea did not have allochthonous material inside them (Fig. 2). These bladders, which were small, anthocyanic, and had bladder doors that were not fully developed (Figs. 4, 5), were on leaf whorls 2–4 plastochrons younger than the first whorl of mature leaves. The youngest leaf with bladder contents was two plastochrons younger than the first mature leaves (Fig. 2). From this leaf whorl the number of occupied bladders increased exponentially with leaf age until bladders in the leaf one plastochron older than the first mature leaf were almost 100% occupied (Figs. 2, 4–9). The amount of material in each bladder also increased with increasing leaf age (Figs. 5, 6, 8). Occupied bladders contained a mixture of living and detrital material. All bladders with contents had some type of photosynthetic tenants, primarily blue–green algae, diatoms, green algae, and/or photosynthetic protists (Figs. 7, 9). Many bladders also had living rotifers. A variety of larger organisms, such as copepods, ostracods, and cladocerans, were found more rarely. At sites A and C, 880 of 1400 bladders examined from different-aged leaves had contents. Of these, 20.2% had living rotifers, 5.1% had cladocerans, 1.3% had chironomids, 0.6% had ostracods, 0.5% had copepods, and 0.9% had other multicellular invertebrates. The rotifers in these samples were swimming around in the bladders, whereas the larger invertebrates were usually dead.

View larger version (11K): [in this window] [in a new window]   Fig. 2. Percentage of occupied bladders by leaf age; 0 = first mature whorl of leaves. Younger leaf whorls are numbered negatively, older leaf whorls are positive. N = 30 plants, with 4–6 leaf whorls and one leaf per whorl examined per plant; 20 bladders were analyzed per leaf. Error bars = 1 SD

View larger version (13K): [in this window] [in a new window]   Fig. 10. Average number of new leaf whorls produced by U. purpurea per week measured at 1–4 mo intervals between June 1997 and November 1998. Data from sites A, B, and C combined. N 80 for each point. Error bars = ±1 SD

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION LITERATURE CITED

Investment in bladders
Species of Utricularia invest a large proportion of their biomass in bladders. While U. purpurea invested approximately one-quarter of its biomass in bladders, U. macrorhiza growing in lakes in northern Wisconsin invested 38–48% (Knight and Frost, 1991 ), and U. vulgaris growing in disused clay pits in Cambridgeshire, UK, invested 50% biomass in bladders (Friday, 1992 ). I have also found an average of 29% investment in bladders from plants collected from a pond on the Florida International University campus (J. H. Richards, Florida International University, unpublished data). This percentage investment is similar to what terrestrial plants in moderately low-nutrient environments invest in root biomass (Tilman, 1988 )

The percentage of biomass invested in bladders is plastic and can vary with environmental conditions. In all studies that have considered the question, the largest variation in bladder number is between sites. In U. purpurea, as in other species of Utricularia (Knight and Frost, 1991 ; Friday, 1992 ), variation among leaves on a plant sampled at a single time is usually minor. Variation among plants at a single site is more complex and probably represents the degree of habitat heterogeneity displayed at a particular site. Whereas Knight and Frost (1991) found minor variation in bladder number among plants in a lake, Friday (1992) found large variation among plants at a single site. In the data reported here U. purpurea bladder number varied among plants both within and between sites.

Benefits from bladders
The conventional view of bladderwort carnivory is that these plants benefit from nutrients derived by digestion of trapped microinvertebrates (Friday, 1989 ; Juniper, Robins, and Joel, 1989 ; Knight and Frost, 1991 ; Ulanowicz, 1995 ). In south Florida bladders of U. purpurea on plants in natural habitats trap very low percentages of these microinvertebrates, except for rotifers, and the rotifers observed inside bladders were alive. Similarly low invertebrate trapping rates were found for U. foliosa in the Everglades (Bern, 1997 ; A. Bern, J. H. Richards, and B. Fry, Florida International University, unpublished data). Calculations of how much nitrogen and phosphorus plants could derive from these trapping rates, if the only benefit is from digestion of microinvertebrates, suggest that the return on a 25–50% investment in bladders is <1% of the plant N and P (Bern, 1997 ; A. Bern, J. H. Richards, and B. Fry, Florida International University, unpublished data).

Although plants had few bladders with dead microinvertebrates, almost 100% of mature U. purpurea bladders supported living communities of microorganisms and associated detritus. These communities were derived from the external environment, as very young bladders lacked them, and the number of inhabited bladders, as well as inhabitant density and diversity, increased over time. The ubiquitous presence of these communities supports the hypothesis that Utricularia plants derive more benefit from by-products of this community than from carnivory, i.e., that the important association in Utricularia bladders is a mutualism rather than a predator–prey interaction. The bladders in Utricularia, therefore, may provide benefit through a detrital food web rather than a carnivorous interaction.

This view is a simplification of Ulanowicz's (1995) positive feedback model for Utricularia carnivory, in which the benefit funneled to Utricularia from periphyton comes through ingestion of animal grazers. In the model this benefit allows Utricularia carnivory to be advantageous in oligotrophic environments (Ulanowicz, 1995 ). I suggest that the carnivory part of the periphyton-Utricularia association may be incidental to the direct interaction.

In the summer plants expand a leaf whorl about every 5 d, and they begin trapping in -2 leaves, so they become 100% occupied after 15 d. Free-floating plants generally have at least three whorls of mature leaves before they become completely covered with algae and appear to be senescent. Thus, after bladders are fully occupied, they may support these communities for another 15 d. After a bladder has been tripped, it can reset itself (Lloyd, 1933; Sydenham and Findlay, 1975 ; Juniper, Robins, and Joel, 1989 ). Whether communities are constantly augmented by material from new trapping events or whether bladder contents increase through reproduction inside the bladders is unknown.

Although the importance of the Utricularia-periphyton interaction has been recognized (Friday, 1989 ; Ulanowicz, 1995 ), the possible importance of the direct interaction has been overshadowed by concepts derived from models of carnivory. The interpretation of the benefit of carnivory presented here provides an explanation for Knight and Frost's (1989) otherwise anomalous result that U. macrorhiza plants in more nutrient-rich environments invested more in bladders. If the benefit of the bladders depends on the productivity of the microcommunity and that productivity increases with increased nutrients, plants would be predicted to produce more bladders under increased nutrient levels.

Currency of the "carnivorous" interaction in aquatic plants
Utricularia is the most diverse genus of carnivorous plants, accounting for a little less than half of all carnivorous species (Juniper, Robins, and Joel, 1989 ), but the genus is unusual in having submerged aquatic species. The interaction in an aquatic species, such as Utricularia purpurea, may differ substantially from carnivory in terrestrial species of Utricularia or in species of other carnivorous plants. If the community interaction inside bladders provides the benefit for investment of biomass in bladders in U. purpurea, the currency in the interaction may not be solely mineral nutrients. For example, carbon dioxide concentrations potentially limit photosynthesis in freshwater aquatic plants (Falkowski and Raven, 1997 ). Carbon dioxide derived from respiratory processes in the bladders could be a significant benefit in the slow-moving aquatic environments typical for some Utricularia species, similar to the benefit obtained from CO₂ uptake through the roots in isoetids (Raven et al., 1988 ). This benefit could help to explain Utricularia's success in the aquatic environment. The endangered Aldrovanda vesiculosa (Droseraceae), a miniature aquatic version of Dionea, is the only other free-floating aquatic carnivorous species. A recent study found that the most important condition for rapid growth in A. vesiculosa was a high-CO₂ concentration in the water (Adamec, 1997 ).

In addition to the possible benefit of CO₂ supplements, bladders in aquatic species could also be advantageous because they provide a contained microenvironment to enhance breakdown of organic matter, prevent diffusion of the breakdown products, and provide Utricularia plants with a monopoly on released nutrients.

Bladder mechanics and community dynamics
The absence of microinvertebrates from many bladders coupled with the presence of some type of material in all of the bladders means either that trapping is very inefficient or that bladders do not require animals to trip them under natural conditions. Alternative possibilities that need to be investigated are (1) debris carried by currents or the current itself is sufficient to cause opening or (2) endogenous factors, such as internal tension, can cause bladder opening. Lloyd (1933) reports that movement of U. purpurea plants in water often releases the traps.

	FOOTNOTES

 
¹ The author thanks Dr. Evelyn Gaiser for help identifying algae and microinvertebrates, Tina Ugarte for technical assistance, and Dr. David Lee, Dr. Tom Frost and Dr. Rolf Rutishauser for constructive reviews. This research was completed as an ancillary project to ongoing research at Florida International University's Southeast Environmental Research Center (FIU SERC). Access to field sites was provided by the SERC ecosystem project "Numerical interpretation of Class III narrative nutrient water criteria for Everglades Wetlands," funded through Cooperative Agreement CA5000–3–9030. Plants were collected under USDI National Park Service collecting permit numbers 19970026 and 19980065.

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