Abstract
The structure of perigonal nectaries, nectar production and carbohydrate composition were compared at various stages in the lifespan of the flower of Fritillaria meleagris L. The six nectaries each occupied a groove that is located 2–4 mm above the tepal base. The average nectary measured 11.0 mm long and 1.0–1.2 mm wide. The structure of nectaries situated on both inner and outer tepal whorls was identical, and at anthesis they were equally accessible to potential pollinators. However, secretion from nectaries associated with inner tepals tended to exceed that produced by nectaries located on the outer tepals. On average, regardless of flower stage, one flower secreted 10.87 ± 12.98 mg of nectar (mean and SD; N = 182). The nectar concentration ranged between 3 and 75%, with average concentration of sugars exceeding 50%. Both nectar production and concentration were dependent on the stage of anthesis, with the highest scores being recorded during full anthesis (21.75 ± 16.08 mg; 70.5%, mass and concentration, respectively) and the lowest at the end of anthesis (1.32 ± 2.69 mg; 16.9%, mass and concentration, respectively). A decline in both mass of nectar secreted and nectar concentration during the final stage of anthesis indicates nectar resorption. Nectar was composed of sucrose, glucose and fructose in approx. equal quantities, and its composition did not change significantly during subsequent stages of flowering. The nectaries comprised a single-layered secretory epidermis and several layers of subepidermal parenchyma. The nectariferous cells did not accumulate starch during any of the investigated stages. The nectary was supplied with one large and several smaller vascular bundles comprising xylem and phloem. Transport of assimilates and nectar secretion by protoplasts of secretory cells (and probably also nectar resorption) were facilitated by cell wall ingrowths present on the tangential walls of epidermal cells and subepidermal parenchyma. Epidermal cells lacked stomata. Nectar passed across the cell wall and through the cuticle which was clearly perforated with pores.
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Introduction
Floral nectar is the main reward offered by plants to pollinators, and it is produced by specialized secretory structures, the floral nectaries. Owing to the importance of nectaries in pollination, the location of nectar secretion and presentation, combined with nectar quantity and composition, are the main factors in determining potential pollinators among nectar-feeding animals (Simpson and Neff 1983; Pacini et al. 2003; Pacini and Nepi 2007).
Unlike the floral organs, whose relative positions are conserved across the angiosperms, the nectary glands can be found at various floral and extrafloral locations and, according to the studies of Baum et al. (2001), location of the nectary is independent of the ABC floral homeotic genes. This enables a shift in nectary position over evolutionary time in response to selection imposed by interactions with pollinators. Therefore, nectaries can arise at any position along the receptacle, or equally, can be associated with any floral organ (Bernardello 2007, and references therein).
Perigonal type of nectaries are located on perianth parts (tepals, sepals and petals) and they commonly occur in both dicotyledonous and monocotyledonous plants. In the latter, they are found in Liliaceae and several other families, such as Orchidaceae, Triuridaceae, Calochartaceae, Alstroemeriaceae, Luzuriagaceae, Melanthiaceae and Iridaceae. They are present in most members of the subfamily Iridoideae, but in Nivenioideae and Crocoideae, nectaries are of the septal type (Vogel 1998; Rudall et al. 2000; 2003; Smets et al. 2000; Goldblatt and Manning 2008). Perigonal nectaries may be glandular, glabrous or trichomatous and are located at the base of perianth segments in Iridaceae (Rudall et al. 2003) and Liliaceae (Bakhshi Khaniki and Persson 1997; Stolar and Davis 2010).
The position and structure of nectaries and the composition of their nectar provide important taxonomic characters (Percival 1961; Baker and Baker 1983; Endress 1995; Rudall et al. 2000, 2003; Smets et al. 2000; van Wyk 2002; Rønsted et al. 2005; Bernardello 2007). This is also the case for the relatively large genus Fritillaria L., which comprises about 130 species of diverse habit and flower morphology. Furthermore, differences in the position and morphology of nectaries have frequently been used as a basis for subgeneric classifications (Bakhshi Khaniki and Persson 1997; Bakhshi Khaniki 2007).
Although scanning electron microscopy (SEM) studies provide comprehensive information on the morphology of the nectaries in many representatives of Asiatic Fritillaria, there are a paucity of data with regard to the anatomy and ultrastructure of nectaries in this genus. This is also true of the family Liliaceae, which currently contains 16 genera (Fay and Chase 2000). Details of the structure of tepalar nectaries in the Asiatic Lilium hybrid Trésor were recently published (Stolar and Davis 2010).
The aim of the present paper is to investigate the anatomy and ultrastructure of the perigonal nectaries of Fritillaria meleagris L., and in particular, to compare the structure of the nectaries and nectar composition during successive stages of nectary activity. Because the flowers were said to be protogynous (Knuth 1899; Rix 1968), we also checked for differences in nectar availability to pollinators between presumed sexual stages of the flower. Our study plant is self-compatible, but seeds in natural conditions are mostly outcrossed (Zych and Stpiczyńska 2012); therefore, interactions with animal pollinators, including nectar production and presentation, are a crucial step in the plant’s reproduction. Flower visitors include bumblebees, honeybees, solitary bees and flies (Knuth 1899; Hedström 1983; Zych and Stpiczyńska 2012). Although the largest pollen loads are transferred by solitary bees, the main pollinators are bumblebees (mostly Bombus terrestris and B. lapidarius) due to their seasonal and floral constancy, and tolerance of bad weather conditions (Zych and Stpiczyńska 2012). As shown by these authors, the flowers of this early-spring flowering species have very a low visitation rate despite being large and showy; we were, therefore, also interested in whether the plant reabsorbs secreted nectar that is not utilized by insect visitors.
Materials and methods
Study site
The plants of F. meleagris L. (Liliaceae) used in this study came from the natural locality of the species, namely the Szachownica w Krównikach nature reserve (the largest population of F. meleagris in Poland). The reserve occupies an area of 16.7 ha in the village of Krówniki, near Przemyśl (SE Poland, central point N49°46′19″ E22°50′59″). Since 1946, the species has been legally protected in Poland and is currently included in the “critically endangered” category of the Polish red list. It is also red-listed or bears the status of “rare plant” in other European countries within its natural range, and is regarded as “vulnerable” for the whole of Central Europe (Zych and Stpiczyńska 2012, and references therein).
Field observations: phenology, sexual stages and nectar production
In 2009–2011, in order to assess flower longevity and period of nectar production, we randomly marked 20 plants bearing unopened flower buds. Twice daily (in the morning and again in the afternoon), we checked the plants and noted the progress of flowering stages (stage 0—closed bud, about 5 days before opening; stage 1—bud opening with anthers closed; stage 2—beginning of anthesis and pollen presentation, i.e. at least one anther dehisced; stage 3—full anthesis, when all anthers dehisced; stage 4—end of anthesis; stage 5—flower wilting) and the presence of nectar.
Nectar sampling
The initial and final stages of nectar production were assessed on the basis of observations made on the progress of flowering. Nectar was sampled from the flowers at the first day of anthesis (stage 2), from the 3- to 3.5-day-old flowers (stage 3), and at the final stage of anthesis (approx. 5–6th flowering day, stage 4). For this purpose, samples of 20 flowers designated for nectar sampling at appropriate stages were chosen randomly while the buds were still closed (about 5 days before opening) and bagged with a nylon net (mesh 0.5 mm) to prevent visits by insects. When the flower reached the required stage of development, the nectar from each of three nectaries associated with the outer whorl (as one sample per flower) was carefully sampled with microcapillary pipettes of known mass and then repeated for three nectaries associated with the inner whorl (also as one sample per flower). The microcapillaries containing nectar were reweighed using an analytical balance AS 60/220/C/2 (RADWAG, Radom, Poland) in order to determine the mass of secreted nectar. Nectar was subsequently expelled from the microcapillary onto an RL-4 or RL-3 refractometer prism (PZO, Warszawa, Poland) in order to measure nectar sugar concentration (as percentage nectar concentration by weight).
In 2009, in order to check for changes in the composition of nectar sugars throughout the lifetime of the flower, nectar from five flowers (but this time, without distinction between nectaries associated with outer and inner whorl) for each stage of development (2–4) was collected with wicks of Whatman paper no. 1 of known mass. The nectar-laden wicks were immediately weighed on an analytical balance, then were air-dried and stored at −20°C prior to analysis. The samples were thawed to ambient temperature and nectar was then recovered from the filter paper by static elution with 100 μl distilled water for 3–4 min, followed by centrifugation for 5 min at 11,000g (rcf). The supernatant was analysed by isocratic HPLC using an LC1 Waters system. A 20-μl sample and standard solution were injected. Water (MilliQ, pH 7), with a flow rate of 0.5 ml/min, was used as the mobile phase. Sugars were separated in a Waters Sugar-Pack I column (6.5–300 mm) maintained at 90°C and identified by a refractive index detector (Waters 2410). The contents of fructose, glucose and sucrose were determined and expressed as a percentage of total sugars.
Microscopic observations
The structure of nectaries was studied for the flowers at the stage of bud opening (stage 1) and from stages 2 to 4. The distribution of nectaries derived from fresh flowers was recorded, and an examination of their surface undertaken using a Nikon SMZ 1000 stereomicroscope (Nikon Corp., Tokyo, Japan). The nectaries were then prepared for histochemical investigations by means of light microscopy (LM), transmission electron microscopy (TEM) and SEM. For bright field LM, hand-cut sections from fresh nectaries were stained for lipids and starch using an alcoholic solution of Sudan IV and IKI, respectively (Jensen 1962). Semi-thin sections of nectaries were prepared by fixing nectary tissue in 2.5% glutaraldehyde/4% formaldehyde in phosphate buffer (pH 7.4; 0.1 M) for 4 h at 4°C, followed by three washes in phosphate buffer. Samples were subsequently dehydrated in a graded ethanol series and infiltrated with LR White resin. Following polymerization at 60°C, the sections were cut with a glass knife at a thickness of 0.9–1.0 μm. For general histology, semi-thin sections were stained with 0.25% toluidine blue O (TBO) in 0.25% (w/v) aqueous sodium tetraborate solution (O’Brien and McCully 1981) or with Multiple Stain Solution (MSS) (Polysciences, Inc., Eppelheim, Germany) (that appears to differentiate cell walls more effectively), used according to the protocol provided by the manufacturer. LM observations were conducted using a Nikon Eclipse 400 (Nikon Corp., Tokyo, Japan) microscope and measurements were taken with NIS-Elements Br 2 imaging software (Nikon Corp., Tokyo, Japan).
The sections were also examined by means of fluorescence microscopy (FM). In order to test for the presence of callose and cutinized cell walls, semi-thin sections were stained with aniline blue and auramine O, respectively (Johansen 1940; Heslop-Harrison 1977; Gahan 1984). A Nikon 90i fluorescence microscope with UV2A filter (EXP. 378/11; DM 416; BA 416 LP) was used for sections stained with aniline blue, whereas a FITC filter (EXP. 465-495, DM 505; BA 515-555) was used for sections stained with auramine O. Autofluorescence of hand-sectioned material, when illuminated with UV light, was used to detect the distribution of chloroplasts and lignified nectary cells. Photomicrography was undertaken using either a Nikon 90i fluorescence microscope with digital camera (Nikon Fi1) and NIS-Elements Br 2 software, or a Zeiss AxioImager Z1 fluorescence microscope equipped with an AxioCam MR digital camera.
Material for TEM was fixed as above, but then post-fixed in 1% osmium tetroxide solution at 0°C for 1.5 h, washed in distilled water and dehydrated using a graded ethanol series and embedded in LR White resin. Ultra-thin sections were cut with a glass knife at 60 nm using a Reichert Ultracut-S ultramicrotome (Reichert Jung, Wetzlar, Germany), stained with uranyl acetate and lead citrate (Reynolds 1963) and examined using Zeiss Leo EM 912 (Zeiss SMT GmbH, Göttingen, Germany) transmission electron microscope, at an accelerating voltage of 90 kV.
For SEM observations, nectaries fixed as above were dehydrated in acetone, subjected to critical-point drying using liquid CO2, sputter-coated with gold and examined using a TESCAN/VEGA LMU SEM (TESCAN, Brno, Czech Republic) at an accelerating voltage of 30 kV.
Results
Nectar secretion, concentration and composition
The floral nectar of F. meleagris was secreted by tepalar nectaries positioned adaxially on each of six perianth segments (Fig. 1a, b). The nectaries were depressed in a groove located 2–4 mm above the base of the tepal (Fig. 1b, c). The proximal part of the nectary was wider (mean 5.4 mm) than the remaining part (range 1.0–1.2 mm wide). The length of the whole nectary varied from 9.12 to 14.43 mm (11.0 ± 1.49 mm; mean and SD). All the nectaries, regardless of whether they were located on the inner or outer tepals, were of similar size and, at anthesis, were equally accessible to potential pollinators (Fig. 1a). The light green nectaries contrasted markedly with the white and dark-purple patterned tepals (Fig. 1a, b), However, some nectariferous cells appeared coloured, as they contained anthocyanins.
On average, a single tepalar whorl secreted 5.43 ± 6.64 mg of nectar, whereas one flower secreted 10.87 ± 12.98 mg of nectar. The nectar concentration ranged between 3 and 75%, with average sugar concentration exceeding 50% (means and SDs calculated across years and floral stages). However, both nectar production and concentration were dependent on the floral stage sampled (two-way ANOVAs with study year and flower stage as factors: F 2,173 = 74.496 for nectar mass and F 2,92 = 113.716 for nectar concentration; p ≪ 0.001 for both variables), with the highest scores, on average, obtained for flowers displaying full anthesis (21.75 ± 16.08 mg; 70.5% mass and concentration, respectively) and the lowest towards the end of anthesis (1.32 ± 2.69 mg; 16.9% mass and concentration, respectively). Intermediate results were obtained for flowers at the beginning of anthesis (9.85 ± 5.81 mg, 44% mass and concentration, respectively; Fig. 2). Nectar production also varied from year to year (two-way ANOVA on nectar mass with study year and flower stage as factors, F 2,173 = 7.109, p < 0.002); the greatest and lowest values being obtained for 2010 and 2009, respectively (Fig. 2). When the perianth whorls were considered separately, the inner three tepals (inner whorl) produced approx. 20% more nectar than the outer whorl (multivariate ANOVA on nectar mass with study year, floral stage and tepal position as factors: F 1,346 = 6.292, p < 0.02 for outer vs. inner whorl).
The nectar contained sucrose, glucose and fructose in approx. equal quantities, with fructose slightly exceeding glucose and sucrose in the nectar profile of all stages investigated (33:28:39, sucrose/glucose/fructose ratio expressed as a relative percentage of total sugars; means calculated across flowering stages). No other sugars were detected in the nectar. Nectar composition did not change significantly during subsequent stages of flowering (Fig. 3).
Small droplets of nectar appeared on the surface of the nectary at a stage when the buds were just opening (stage 1, Fig. 4a), the anthers had not dehisced and the stigma was not receptive. Nectar was still present on the nectary surface until stage 4, but then disappeared. This coincided with tepals losing their turgor and the flower reassuming a bud-like form.
The structure of nectaries
The nectary consisted of a single-layered epidermis lacking stomata and 3–4 layers of subepidermal nectariferous parenchyma (Fig. 4b–h). The epidermis was composed of small cells, some 33.85 × 25.16 μm in diameter. The cytoplasm of each epidermal cell stained intensely and contained a large, centrally located nucleus, several small vacuoles and proplastids (Fig. 4c–e, g).
Subepidermal nectariferous parenchyma cells had a mean diameter of 34.45 μm. They contained larger vacuoles than epidermal cells. Vacuoles had translucent contents and were traversed by cytoplasmic strands (Fig. 4c–e, g). Perinuclear and parietal cytoplasm contained numerous plastids (Fig. 4c). Plastids were also located more deeply within the nectariferous parenchyma, but these cells showed only pale red autofluorescence (Fig. 4h).Treatment with IKI did not reveal the presence of starch in the plastids of nectariferous cells.
Nectariferous tissue (measured above midrib, at the proximal end of the nectary) was 255.71–380.5 μm deep, and similar values were also recorded for subsequent stages of nectary activity. Beneath the nectary tissue lay several layers of larger ground parenchyma cells having prominent intercellular spaces. The nectary was supplied by a single, main vascular bundle and several small bundles that ended in the subepidermal secretory layer (Fig. 4b, d, h). These bundles contained xylem and phloem elements.
Treatment with TBO revealed that the walls of secretory cells contained cellulose and pectins. Staining with Sudan IV and auramine O did not indicated the presence of suberized parts in the cell walls (Fig. 4d–e, g). Furthermore, aniline blue did not reveal the presence of callose in the cell walls at the beginning of anthesis (Fig. 4f). The thickness of the primary wall varied considerably (Fig. 4e). For example, on average, the outer tangential epidermal wall measured 2.25 μm thick, whereas the inner tangential wall measured 3.15 μm. Both were distinctly thicker than the radial walls (0.45 μm, on average). Similar differences in cell wall thickness were also recorded for subsequent stages of nectary activity. Cell walls of nectariferous parenchyma cells were more uniformly thick and, on average, measured 0.54 μm.
Outer walls of epidermal cells were covered with a thick cuticle. The structure and thickness of the cuticle were uneven and ranged from 0.5 to 3.12 μm. The cuticle, although it did not fluoresce with auramine O (Fig. 4g), nevertheless stained red with Sudan IV (Fig. 4e) and fluoresced an intense red with UV light (Fig. 4h). Frequently, blisters of cuticle were noted (Fig. 4f). TEM observations revealed granular, electron-dense cytoplasm enclosing numerous rough endoplasmic reticulum profiles (rER) that often accumulated in the parietal cytoplasm, secretory vesicles, mitochondria and small vacuoles with flocculent or globular contents. Also, dictyosomes were frequently observed (Fig. 5a, b). Plasmodesmata were rarely encountered, but when present, were mainly found in the radial walls of epidermal cells.
The availability of the secreted nectar increased concomitantly with anthesis (stage 2), and the whole nectary groove became filled with nectar (Fig. 6a). SEM revealed that the secretory surface was clearly different from that of the non-secretory region, because the cuticle had distinct swellings that usually coincided with the position of the middle lamella between adjoining epidermal cells (Fig. 6b).
The size of the epidermal cells and nectariferous parenchyma tended to increase slightly when compared with stage 1 and measured 38.12 × 31.46 μm and 42.05 × 43.28 μm, respectively. In particular, the vacuoles of both types of cell were larger than those found in stage 1 and occupied a greater proportion of some subepidermal parenchyma cells (Fig. 6c). LM observations of this developmental stage also revealed the presence of epidermal and subepidermal cells with intensely stained cytoplasm and large nuclei (Fig. 6d). Starch was absent from nectariferous tissue, but was present in minute quantities in phloem and xylem parenchyma cells. The middle lamella cementing the inner tangential wall of the epidermis to that of the adjacent parenchyma cell was relatively thick (Fig. 6c), and intercellular spaces were occasionally observed. Staining of sections with aniline blue for FM revealed the presence of callose within the cell walls of nectariferous tissue. Furthermore, in stage 2, nectariferous parenchyma cells only fluoresced pale red when subjected to UV light.
The thick cuticle of epidermal cells stained red with Sudan IV. As in stage 1, the cuticle fluoresced pale red with UV light, but did not stain with auramine O, and micro-channels were present in the cuticle (Fig. 6e). At stage 2, inconspicuous, labyrinthine cell wall ingrowths appeared in the outer tangential walls of epidermal cells and in the subepidermal parenchyma (Fig. 6d, e). Under LM, these stained intensely with MSS. This reagent stained the cytoplasm only slightly, thus producing much better contrast than other stains. Ingrowths penetrated the cell lumen to a depth of ca. 2 μm. TEM observations indicated a close association between rER and wall ingrowths (Fig. 6e). At this stage, the cytoplasm had a similar granular appearance to that of cells at stage 1. However, small vacuoles had accumulated, mainly at the centre of the cell (Fig. 6f). In the parietal cytoplasm, especially near the plasmalemma, osmiophilic droplets were present (Fig. 6e). Plastids present in secretory epidermal cells contained dark stroma (Fig. 6f) with several small plastoglobuli, but few lamellae.
At full anthesis (stage 3), the nectaries were completely covered with secretion and nectar extended beyond the nectary groove (Fig. 7a). SEM revealed numerous cuticular blisters. These were larger than in the previous stage and were distributed along the outer epidermal cell walls (Fig. 7b). Often, perforations were visible on these cuticular blisters, as well as nectar residues.
As in the earlier stages, nectariferous cells contained dense, intensely stained protoplasts with large nuclei (Fig. 7c, d), and starchless plastids could be seen in the parenchyma (Fig. 7e). At stage 3, cell wall ingrowths of epidermal and subepidermal cells were more prominent and longer (Fig. 7d, f, g), but, in contrast to the previous stage, TEM observations also revealed that these outgrowths became coated with a thin layer of callose (Fig. 8a–c). This substance was detectable using FM following staining with aniline blue (Fig. 7f). Ingrowths occurred not only on tangential walls, but also on parts of the radial walls of epidermal cells (Fig. 8c). The layer of callose coating the radial walls and tangential walls of subepidermal parenchyma was not visible using TEM (Fig. 8d–f). The outer tangential walls of epidermal cells were covered with blistered cuticle containing micro-channels (Fig. 8a). The electron-dense cytoplasm mainly contained secretory vesicles and small vacuoles with flocculent contents, but in contrast to stage 2, they were found close to the cell wall ingrowths and in the central cytoplasm (Fig. 8c–e).
At the final stage of anthesis (stage 4) only nectar residues were present on the surface of the nectary. Some cells of the nectariferous epidermis still contained dense cytoplasm, but others contained less dense or watery cytoplasm, or had completely collapsed (Fig. 9a–d). The epidermal cuticle did not stain with auramine O. Furthermore, the red autofluorescence produced on exposure to UV light was less intense, and the cuticle fluoresced pale blue. Cell wall ingrowths did not disappear with a decline in secretory activity (Fig. 9c, e, f) and callose remained a component of the cell wall. Numerous secretory vesicles of various size, together with small vacuoles, occurred in cytoplasm. These had darker and more compact contents than cells in previous stages of nectary activity (Fig. 9g). In subepidermal parenchyma cells, the cytoplasm tended to be electron-transparent and most organelles lost their structural integrity.
Discussion
Nectar secretion and resorption
Our studies on the pollination biology of F. meleagris showed that the flowers are homogamous and that stigma receptivity and anthers dehiscence occur simultaneously (Zych and Stpiczyńska 2012). Therefore, protogyny in this species, as previously reported by Knuth (1899), was not confirmed. Moreover, the period of maximum nectar secretion overlapped with maximum pollen presentation and stigmatic receptivity. Accumulation of the rewards (nectar and pollen) at a given time may enhance the attractiveness of the flower to pollinators and allow maximum benefit from just a single visit, especially because the frequency of pollinator visits to the flowers of the European Fritillary is so low. Indeed, during 3 years of observations, we noted only about 0.2 visits/flower/h (Zych and Stpiczyńska 2012). However, the presence of nectaries alone most probably does not affect attractiveness of the flowers as they are green and invisible to pollinators from outside of the flower, contrary to the nectaries of ornithophilous Fritillaria species (Cronk and Ojeda 2008).
The flowers of F. meleagris produce a considerable amount of pollen and nectar and these are an important food source for hymenopterans visiting the plants during early spring. The nectar was relatively concentrated and was presented on a relatively exposed surface of each nectary within the flower. In F. meleagris, there are no furrows or lobes present as in some other Fritillaria (Bakhshi Khaniki and Persson 1997) and Lilium species (Stolar and Davis 2010) that could restrict the feeding of insects with relatively long proboscises on nectar. However, the nodding of flowers of F. meleagris limits access to the reward to a relatively small group visitors, predominantly large Hymenoptera (Zych and Stpiczyńska 2012). On the other hand, the pendant flowers of F. imperialis L. are pollinated by passerine birds in its native range (Búrquez 1989; Peters et al. 1995; Cronk and Ojeda 2008). A high rate of nectar secretion of very low solute concentration (4–10% w/w), the absence of sucrose from the nectar, and the low amino acid concentration are all indicative of passerine bird pollination. In Europe, as reported by Búrquez (1989) and Peters et al. (1995), this ornamental plant is visited by blue tits (Parus caeruleus L.) and bumblebees, and ornithophily in crown imperial was confirmed by the fact that flowers visited by blue tits are efficiently pollinated and fertilized (Búrquez 1989). Even incidental ornithogamy in F. meleagris seems impossible, mainly due to inappropriate nectar composition and secondly because the flowers are not sufficiently robust to offer a suitable perch to feeding birds.
In our study plant, nectar was presented to pollinators for approx. 5–6 days (Zych and Stpiczyńska 2012). Similarly, nectar is available for 5 days in the Lilium hybrid Trésor, whereas in other Asiatic hybrids of Lilium, nectar was secreted only for 1 day (Lee and Chi 2002).
In F. meleagris, the mass of nectar secreted by the nectaries of the inner tepals was 20% higher than those of the outer tepals. However, nectary morphology are similar, irrespective of their position, and any variation in secretory activity might result from the somewhat larger tepals of the inner whorl. On the other hand, the Lilium hybrid Trésor displays a clear distinction between the perianth segments, but each petal and sepal produces a comparable amount of nectar sugars (Stolar and Davis 2010).
In F. meleagris nectar was composed of almost equal quantities of sucrose, glucose and fructose, and this balance did not change in successive stages of anthesis. Our results agree with the findings of Rix and Rast (1975) for the same species. However, in other species of Fritillaria investigated by these authors, nectar composition differed in particular taxonomic sections. For example, in F. imperialis no sucrose was detected, whereas members of the other series of section Trichostylae Boiss. showed that fructose was distinctly dominant to glucose. Conversely, in Lilium, sucrose was the most abundant nectar sugar (Stolar and Davis 2010). These results can probably be attributed to differences in pollinating agents, but field data for many Fritillaria and Lilium species are unfortunately scarce.
In the final stage of anthesis, the mass of nectar and its concentration declined significantly, which indicates that nectar resorption occurs in the flowers of F. meleagris. Nectar resorption is a long-known phenomenon, but has rarely been addressed in studies on nectar secretion (Pedersen et al. 1958; Southwick 1984; Pyke 1991; Búrquez and Corbet 1991; Nepi and Stpiczyńska 2008). Resorption of nectar has generally been demonstrated (as in Fritillary) during final stages of anthesis as a post-pollination phenomenon (Koopowitz and Marchant 1998; Luyt and Johnson 2002) or following the completion of sexual stages in dichogamous flowers (Langenberger and Davis 2002). Its significance was generally recognized as a resource-recovery strategy, and resulted in at least partial recycling of metabolites invested in nectar production (Southwick 1984; Pyke 1991; Búrquez and Corbet 1991; Nepi and Stpiczyńska 2007). However, nectar resorption can also occur concomitantly with nectar secretion, as shown for Cucurbita pepo. Moreover, the modulation of these two contrasting processes (secretion and resorption) allows the maintenance of nectar composition within a range appropriate for pollinators (Nepi et al. 2007). It should be noted that in the European Fritillary, all nectar sugar constituents were resorbed to a similar degree, because the proportion of individual sugars at the final stage of anthesis remained almost unchanged. This result compares well with that obtained for Eucalyptus (Davis 1997).
Reclamation of nectar components in Fritillary is facilitated by the presence of micro-channels or pores in the cuticle that covers the secretory epidermis, as in Echinacea purpurea L. (Moench) (Wist and Davis 2006), P. chlorantha (Stpiczyńska 2003a) and C. pepo (Nepi et al. 2001). Also, in F. meleagris, the efficiency of nectar resorption is improved by the wall ingrowths present in the cells of the nectariferous epidermis and parenchyma, and these were still present at the final stages of anthesis, when nectar resorption occurs. Resorbed nectar can be translocated along the symplast and/or apoplast, and then transported in vascular tissue to the nearest major sink of assimilates. The route taken by secreted nectar was confirmed by autoradiographic studies of P. chlorantha. Here, resorbed sugars were translocated acropetally or basipetally along the whole inflorescence (Nepi and Stpiczyńska 2007).
Nectary structure
The nectaries of F. meleagris are located in grooves on the adaxial surfaces of each of the tepals (Knuth 1899). In general, the morphology of the nectaries of F. meleagris is similar to that reported by Bakhshi Khaniki and Persson (1997) for several species of the subgenus Fritillaria, the nectary of each possessing a lanceolate to linear outline. By contrast, in the subgenus Petilium (L.) Baker, which includes F. imperialis and F. raddeana, nectaries are circular, whereas those of the subgenus Rhinopetalum (Fisch. ex Alexand.) Baker, have nectaries that are deeply depressed and situated in sac-like projections that can either be symmetrical on each tepal or unequal. In the latter case, the flowers tend to be zygomorphic. Moreover, in the subgenus Rhinopetalum, the nectary surface is bordered by lobes or hairy ridges, like the perigonal nectaries of Lilium (Stolar and Davis 2010), whereas in F. meleagris, the surfaces of the nectary and tepals are completely glabrous. Details of the morphology and as well structure of nectaries could be important characters in determining classification and evolution of the genus Fritillaria and other Monocotyledons (Smets et al. 2000). However, up to date morphological aspects of the nectary in Asiatic Fritillaria were considered by Bakhshi Khaniki and Persson (1997) and structural aspects are still neglected.
In F. meleagris, the nectaries positioned on the tepals of the outer and inner whorls differed neither in their morphology nor their anatomy. Similarly, no evident morphological differences were reported for other species of the genus (Bakhshi Khaniki and Persson 1997).
The nectary of F. meleagris was composed of a secretory epidermis and several layers of nectariferous parenchyma. This model of nectary structure has been reported for many other plant species (Durkee 1983; Fahn 1979, 1988, 2000; Bernardello 2007; Nepi 2007; Davies and Stpiczyńska 2008), regardless of taxonomic position and nectary location (e.g. ‘nectaria caduca’ and ‘nectaria persistentia’ sensu Smets and Crescens 1988). Moreover, the secretory cells of F. meleagris share many features with the nectaries of other plant species in that they are small with large nuclei, small vacuoles and dense, intensely staining cytoplasm with abundant endoplasmic reticulum, dictyosomes and secretory vesicles. However, contrary to the majority of nectaries investigated, where amyloplasts or chloroamyloplasts were present at least in the pre-secretory stage, starch was not detected in the nectary cells of F. meleagris. Starchless plastids similar to those present in Fritillary, with numerous plastoglobuli and few internal membranes, have rarely been observed in nectary cells, e.g. in Gymnadenia conopsea (Stpiczyńska and Matusiewicz 2001) and Maxillaria coccinea (Jacq.) L.O. Williams ex Hodge (Stpiczyńska et al. 2004), but in the latter, the nectary was studied only at full anthesis. In the majority of nectaries studied, plastids usually became differentiated into amyloplasts, and these play an important role in nectar production. According to the mechanism postulated by Ren et al. (2007) for Nicotiana, starch stored in amyloplasts at the pre-secretory stage is hydrolysed during the secretory stage and serves both as a source of carbohydrate for nectar and as a source of energy to pump sugars from the phloem into the nectary. As starch was absent from the nectary cells of F. meleagris, sugars secreted in the nectar were probably delivered by the phloem sap, because nectariferous tissue was supplied with vascular bundles that ended in the subepidermal parenchyma. Van Die et al. (1970) showed that following application of 14C to the leaves of F. imperialis, radioactive label appeared in the floral nectar, indicating that nectar assimilates can be translocated directly from leaves. Because plastids present in the nectariferous parenchyma cells of F. meleagris did not display characteristic red fluorescence (it is possible that such pale red dispersed autofluorescence is affected by the presence of anthocyanins), they are probably not engaged in contributing assimilates to the nectar, as recorded for other plant species (Pacini and Nepi 2007; Vassiliev 2010; Heil 2011).
The nectary cells of epidermal and subepidermal parenchyma of F. meleagris had unevenly thickened cell walls, the tangential walls being significantly thicker than the radial ones. Similarly thickened cell walls were recorded for the perigonal nectaries of Lilium (Stolar and Davis 2010). Moreover, collenchymatous cell walls have been reported for the nectaries of several orchid species, particularly those taxa pollinated by birds (Stpiczyńska et al. 2004; Davies et al. 2005). In Fritillary, as in other species, thick cell walls may serve as a route for nectar transport within nectary tissue, especially where cutinized barriers that could inhibit nectar flow are absent from the wall. Plasmodesmata connect secretory cells and are particularly common in radial cell walls where they may facilitate additional transport of nectar along the symplast. These models of pre-nectar movement along the apoplast and/or symplast within secretory tissue, as well as the process of secretion, were proposed by several researchers (Gunning and Hughes 1976; Kronestedt-Robards and Robards 1991; Nepi 2007; Vassiliev 2010; Heil 2011). Some studies used radiolabelled sugars to follow the route taken by sugars within the nectary (Shuel 1961; Fahn and Rachmilevitz 1975; Meyberg and Kristen 1981; Sawidis et al. 1989; Stpiczyńska 2003a, b; Nepi and Stpiczyńska 2007; Ren et al. 2007). According to Bush (1999), Williams et al. (2000) and Lemoine (2000), both pathways of sucrose transport may operate in the same plant, with particular routes favouring a specific organ, tissue or developmental stage. Sucrose may be imported into sink cells from the apoplast, either directly by sucrose transporters or by monosaccharide transporters following hydrolysis to glucose and fructose by cell wall invertase. Within the protoplasts of nectary cells, nectar undergoes a final modification and is subsequently secreted into the periplasmic space. Because in the nectary cells of F. meleagris both secretory vesicles and numerous mitochondria were present at the secretory stage, it is probable that sugars are actively transported across the plasmalemma and that a granulocrine mode of secretion operates here, as in the nectaries of many other plant species (Kronestedt-Robards and Robards 1991; Fahn 2000; Nepi 2007).
For the first time, we report the presence of transfer cells with prominent labyrinthine wall ingrowths for the perigonal nectaries of Fritillary. Cell wall ingrowths were absent from the perigonal nectaries of Lilium (Stolar and Davis 2010), but small cell wall ingrowths were observed for the septal nectaries of Tillandsia (Fiordi and Panandri 1982). Prominent wall ingrowths have also been recorded for the septal nectaries of Gasteria, Aloe (Schnepf and Pross 1976) and Strelitzia (Kronestedt-Robards and Robards 1987). However, cell wall ingrowths are a universal feature of plants and fungi, and can develop in the cells of many organs (for review see Offler et al. 2002). In F. meleagris, nectariferous cell wall ingrowths were particularly prominent on the tangential walls of epidermal and nectariferous parenchyma cells at the stage of maximum secretory activity. Generally, cells with wall ingrowths are frequently termed transfer cells, because the presence of wall ingrowths increases the surface area of the plasmalemma and thus improves transport capacity. The presence of wall ingrowths also frequently polarizes the direction of solute flow, and it is thought to facilitate the exchange of solutions between apoplast and symplast. Moreover, as in the case of F. meleagris, an endomembrane secretory system is located close to the wall ingrowths (Gunning and Pate 1969; Offler et al. 2002). It is possible that cell wall protuberances in F. meleagris facilitate the transport of nectar within the nectary, together with nectar secretion and nectar resorption during the final stage of anthesis, because they are still present and unchanged in nectariferous epidermal cells and subepidermal parenchyma. By contrast, the post-secretory stage cell wall underwent redifferentiation in the septal nectaries of Gasteria and Aloe; ingrowths disappeared and the cell wall became covered by a ‘third layer’ (Schnepf and Pross 1976). Thickening of the tangential cell wall was also reported for Tillandsia (Fiordi and Panandri 1982) and was mainly due to the accumulation of acid polysaccharides.
In the nectariferous cells of F. meleagris, callose was detected in cell walls at the secretory stage, as recorded for Aloe greatheadii var. davyana (Nepi et al. 2006). According to Offler et al. (2002, and references therein), callose is a common component of wall ingrowths and its presence is restricted to the outer layer between the ingrowth and the plasma membrane. The occurrence of callose may facilitate deposition of wall material and push the projections into the cytoplasm.
Usually, once secreted by the protoplast, nectar passes across the cell wall and can flow onto the surface of the nectary via modified stomata, a permeable cuticle or via pores/cracks in the cuticle (Nepi 2007). Modified stomata were absent from the epidermis of F. meleagris, and this is true of the floral nectaries of most monocots (Endress 1995). To date, the only known exception is the orchid Maxillaria anceps Ames and C. Schweinf. (Davies et al. 2005), where nectar is secreted via the stomata of the labellar callus. The thick layer of reticulate cuticle covering the surface of the secretory epidermis of F. meleagris did not pose a barrier to nectar secretion. Having crossed the outer cell wall, nectar accumulated beneath the cuticle, which became distended to form small swellings. At the beginning of nectar secretion (stage 1) these swellings were most frequently found at points coinciding with the middle lamella, between adjoining epidermal cells, and this may strengthen the hypothesis that in the nectary of F. meleagris, nectar passes along the apoplast before traversing the stretched cuticle, which at points becomes ruptured to form pores. These pores were particularly evident during the stage of maximum secretion. Similar cuticular pores have been recorded for the nectary hairs of Abutilon (Findlay and Mercer 1971). In some plants, however, the secretion is released via a disrupted cuticle, as in the nectaries of Limodorum abortivum (Pais and Figueiredo 1994). In others, such as Platanthera chlorantha (Stpiczyńska 2003a, b), the cuticle is completely permeable to secreted substances, as well as resorbed nectar. It is possible that changes to the chemical structure of the cuticle, as demonstrated by differences in autofluorescence during the secretory and postsecretory stages, may further facilitate the secretion and resorption of nectar.
Our studies indicate that F. meleagris is a homogamous plant, and that maximum nectar secretion by perigonal nectaries overlaps with the period of greatest pollen presentation. This greatly improves the effectiveness of pollination. Nectar unused by pollinators is resorbed during the final stage of anthesis. Despite real paths of nectar formation and resorption not being shown here, we speculate that cell wall ingrowths present in nectariferous cells may facilitate both nectar secretion and resorption.
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Acknowledgments
We thank Magdalena Kamińska, M.Sc., for help in the lab and for preparing illustrations, Katarzyna Roguz, B.Sc., for editing the manuscript, Karol Stpiczyński for helping with the field work, Dr. Narcyz Piórecki (Bolestraszyce Arboretum) for hospitality and information on F. meleagris populations in Przemyśl district and Ukraine, and Professor Jakub Dolatowski for translation of Knuth’s (1899) description of F. meleagris. All experimental and observation work on protected plants was done in compliance with Polish law upon obtaining the permissions DOPog-421-II-1/05/jr and DLOPiK-op/ogiz-4211/I-91/6265/07/08/msz from the Ministry of Environment, Republic of Poland, DOPozgiz-4200/I-67.2/1071/10JRO from the General Directorate of Environment Protection, and R.V-6630/41/07 and RDO -18-WPN-6631-2-24/10/rn from the Regional Conservator of Nature in Rzeszów. The study was supported financially by the Ministry of Science and Higher Education, Republic of Poland, via grant N N304 131736 (to MZ and MS).
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Stpiczyńska, M., Nepi, M. & Zych, M. Secretion and composition of nectar and the structure of perigonal nectaries in Fritillaria meleagris L. (Liliaceae). Plant Syst Evol 298, 997–1013 (2012). https://doi.org/10.1007/s00606-012-0609-5
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DOI: https://doi.org/10.1007/s00606-012-0609-5