1. Introduction

Anacardiaceae Lindl. (83 genera, 850 species) is primarily a pantropical family well known for its edible fruits and seeds (e.g. Anacardium occidentale L., cashew; Pistacia vera L., pistachio; Mangifera indica L., mango; Sclerocarya birrea (A. Rich.) Hochst., marula; Schinus terebinthifolia L., peppercorns; fruits from Spondias L. and Tapirira Aubl.) (Pell 2004; Christenhusz and Byang 2016). Extreme variability in floral and fruit characteristics has confounded classification of the group, with the affinity of Anacardiaceae to other families, the placement of certain genera within the family, and intrafamilial classification and species delimitations all being contentious (Pell et al. 2010; Ramirez and Davenport 2016; Muniraja et al. 2018; Tolke et al. 2018). Although Engler's revisions (1881, 1883, 1892) historically have been the most detailed and widely accepted treatments, subsequent revisions based on morphological (Ramirez and Davenport 2016; Muniraja et al. 2018; Tolke et al. 2018) and molecular (Pell 2004) evidence suggest a sustained effort will be needed to better understand relationships within the family.

Common mango (Mangifera indica L.) is among the world's most important fruit crops and the most economically important member of Anacardiaceae ( http://faostat.fao.org/; Mukherjee and Litz 2009). Mango is an andromonoecious tree producing male (staminate) flowers proximally and hermaphroditic flowers distally in terminal panicles (Mukherjee and Litz 2009; Pell et al. 2010; Ramirez and Davenport 2016; Tolke et al. 2018). Both male and hermaphrodite flowers produce one or two large stamens surrounded by three or more staminodes, with staminodes more variable in colour, size, and shape than stamens (Ramirez and Davenport 2016). In both types of flowers, stamens and staminodes are surrounded by flesh disks or nectaries (Singh and Shono 2005; Ramirez and Davenport 2016). Although the ratio of hermaphrodite to male flowers varies by cultivar and geographic location, sex ratios are generally less than 50% (Asif et al. 2002). To date, only general information is available regarding the morphology of anther, staminode, and pollen morphology (Li 1992). Similarly, knowledge on M. indica pollination is limited (Ramirez and Davenport 2016), although flowering and floral morphology recently have been described (Muniraja et al. (2018).

The most definitive taxonomy of Mangifera is that of Kostermans and Bompard (1993) who recognised 69 species, 47 and 11 of which were placed in the subgenera Mangifera and Limus, respectively, leaving 11 of uncertain placement. Shape of the floral disc, number of fertile stamens (and staminodes), inflorescence architecture, petal morphology, and the shape and size of petals and leaves were all important characters in distinguishing subgenera, sections, and species of Mangifera (Kostermans and Bompard 1993). The common mango (M. indica) was included with 14 other species in subg. Mangifera sect. Mangifera based on the number of fertile stamens and staminodes, staminode presence and size, and the number of flowering parts (5-merous; Kostermans and Bompard 1993). More recently, molecular data (Yonemori et al. 2002; Dinesh et al. 2015) or molecular combined with morphological, cytological, and palynological data (Sankaran et al. 2018) have been used to test traditional taxonomies of the genus.

Pollen structure and morphology have been described in several Anacardiaceae (Erdtman 1971; Wunnachit et al. 1992; Belhadj et al. 2007; Pradeep 2014; Bahramabadi et al. 2018), and pollen data hold great promise for addressing longstanding taxonomic issues in the family. For example, distinctive pollen has been described for genera (e.g. Dobinia, Campylopetalum, Pistachia) whose placement in Anacardiaceae has been problematic (Bentham and Hooker 1862; Forman 1954; Melchior 1964; Erdtman 1971; Cronquist 1981; Mitchell and Mori 1987; Mabberley 1997; Takhtajan 1997). Conversely, pollen more typical of Anacardiaceae characterises genera (e.g. Amphipterygium and Orthopterygium) placed in different families based on other morphological characters and subsequently transferred to Anacardiaceae using molecular evidence (Erdtman 1971; Pell 2004). Lastly, pollen data have been used to assess relationships at various taxonomic levels in Anacardiaceae, including among genera (Erdtman 1971), as well as between species within Mangifera (Sankaran et al. 2018).

In mango, the number of pollen grains per anther, pollen shape, and grain size differ among cultivars and between flower types (male or hermaphrodite; Ramirez and Davenport 2010; Gehrke-Velez et al. 2011). Depending on the extent of hydration, the shape of mango pollen varies from spherical to oblong, typically ranges in length from 20 to 45 µm (Mukherjee 1950, Ramirez and Davenport 2016), and is tricolpate (Singh 1961), with each sulcus having a pore in its centre (Mukherjee 1950). Although exine morphologies of male and hermaphrodite flowers are similar (Li 1992), hermaphrodite pollen grains are rounder and larger than those of male flowers (Li 1992).

Environmental conditions at anthesis are critical determinants of pollen viability in mango (Ramirez and Davenport 2016). Particularly important is temperature, with numerous studies documenting decreased viability at lower temperatures (Issarakraisilia and Considine 1994; de Wet and Robbertse 1986; de Wet et al. 1989; Dag et al. 2000; Huang et al. 2010; Geetha et al. 2016). A recent study examining cell wall composition and its influence on somatic–germline cell communications has shed light on the effect of decreased temperature on pollen development and viability in mango (Lora and Hormaza 2018). Muniraja et al. (2018) examined anther wall anatomy and pollen development in fertile anthers of male and hermaphroditic flowers of M. indica, as well as the anatomical features of staminodes in male flowers. Despite these advances, little attention has been paid to anther, staminode, and pollen grain ultrastructure in mango.

The current study examines the ultrastructure of anthers, staminodes, and pollen grains in M. indica using scanning electron microscopy (SEM). We also assessed pollen viability using fluorescein diacetate (FDA) and acetocarmine staining combined with light (LM) and fluorescence microscopy (FM). Our goal is to describe ultrastructural characters of possible taxonomic and reproductive significance in M. indica.

2. Materials and methods

2.2. Methods

2.2.1. Morphology of staminode, anther, and pollen

Sampled tissues (staminode, anther, and pollen) were fixed in 2.5% glutaraldehyde and 2% paraformaldehyde in 0.1 M phosphate buffer (pH 7.4), rinsed in 0.05 M phosphate buffer (pH 7.4), dehydrated in a graded (0–100%) acetone series, and dried on a Bal-Tec 030 critical point dryer. Fixed samples were taped to aluminium stubs with two-sided carbon glue tape, and coated with gold–palladium using an Emitech K550 sputter coater. Observations were made and electron micrographs taken at the Sophisticated Analytical Instrument Facility, All India Institute of Medical Sciences, New Delhi, India, using a Zeiss SEM S-4700 scanning electron microscope (Carl Zeiss, Oberkochen, Germany) operating at 20 kV. Differences in mean anther length and width, staminode length and width, pollen diameter, number of pollen grains per anther, and pollen viability were compared for male and hermaphroditic flowers using t tests.

2.2.2. Anther, staminode, and pollen grain measurements

Lengths and widths of anthers and staminodes from five male and five hermaphroditic flowers at anthesis were measured to the nearest millimetre using an ocular micrometer on a Zeiss light microscope (Carl Zeiss, Oberkochen, Germany) at 100× magnification. Pollen grains were fixed in Carnoy's solution (3:1 absolute ethanol:acetic acid) for 24 h, and stored in 70% (v/v) ethanol at 4 °C until use. Pollen was stained with 2% aceto-carmine and examined under LM (Carl Zeiss, Germany) at 100× magnification, with pollen diameter measured to the nearest micrometre using the integrated software of the microscope. Photomicrographs were captured with a charged-coupled device (CCD) digital camera system (Prog.Res C3 Jenoptik, Jena, Germany). For anther, staminode, and pollen diameter measurements, mean percentages and standard errors were calculated from three replicates, with 12 samples per replicate.

2.2.3. Pollen grain number

Anthers from male and hermaphroditic flowers were dissected and pollen grains transferred to a 5% (v/v) tween-20 solution. After thorough mixing, a haemocytometer chamber was filled with 100 µL of homogeneous pollen grain suspension and grains counted using a light microscope (Carl Zeiss, Germany) at 40×. The number of grains per anther (A) was calculated using the following formula:

where n = pollen grain count per chamber, B = fraction of suspension retained by each chamber in relation to the total suspension volume, and N = number of anthers per total suspension volume (Godini 1981). Three samples of 100 anthers each were prepared and grain counts repeated 3 times per vial, with the number of pollen grains per anther reported as the mean overall count.

2.2.4. Pollen viability

Pollen grains were harvested from dissected anthers and stained directly on a microscope slide in 2.5 mg/mL FDA solution for two minutes (Heslop-Harrison and Heslop-Harrison 1970). The fluorochromatic reaction (FCR) was excited using epifluorescence under blue-light excitation (510 nm dichroic mirror, 525 nm barrier filter, Carl Zeiss, Germany), with viable grains fluorescing yellow-green, and non-viable grains emitting ghost fluorescence. Percentage viability was calculated by dividing the number of yellow-fluorescent microspores by the total number of microspores per field of view multiplied by 100 (Subbarayudu et al. 2014). Mean percentage microspore viability was calculated by averaging percentages over all fields counted from five glass slides.

3. Results

Electron micrographs of ultrastructural features from anthers, staminodes, and pollen are provided in Plate 1–3, respectively. Plate 4 presents photomicrographs of pollen morphology and development (Plate 4, figures 1–2), grain diameter (Plate 4, figures 1–2), and viability (Plate 4, figures 3–4). Morphometric data and statistical results are provided in Table 1.

Table 1.

Anther, staminode, and pollen grain characteristics in male and hermaphrodite flowers.

4. Discussion

We report ultrastructural features of anthers, staminodes, and pollen, as well as pollen counts and viabilities, in mango (M. indica). Several features of potential taxonomic utility are either described here for the first time, or were previously underreported in Anacardiaceae and very poorly known (Muniraja et al. 2018). These include size differences between anthers and staminodes within and between flower types, differences in anther size between flower types, and numerous staminode characteristics that varied between and sometimes within flower types, including the presence of distinct ridges (Plate 2, figure 1), the presence of hook-like outgrowths (Plate 2, figure 2), cell shape and size variability (Plate 2, figure 3), and the occurrence of nectar-secreting stomata on staminode heads (Plate 2, figures 4–6).

Mango anther and staminode heads differed in shape, size, and colour. This dimorphism apparently is a consequence of natural selection for pollen production, or for other functions generally related to pollination and reproductive success (Rodriguez-Riano et al. 2015). We observed differences in anther size between male and hermaphroditic flowers that could result from differing patterns of resource allocation between male and female reproductive functions (Diggle 1993). Alternatively, natural selection may have favoured larger anthers in male flowers, as large anthers are preferred by visiting insect pollinators due to their size and prominence (Wunnachit et al. 1992), or for their pollen-producing capacity in pollen-rewarding species (Johnson and Schiestl 2016). Although the anther lobes of male and hermaphroditic flowers had similar surface morphologies, staminode surfaces were highly variable both within and between flower types compared to anthers (see Plate 1 and 2) (Scholefield 1982). The potential of staminode variation to illuminate phylogenetic relationships in flowering plants has been appreciated by previous authors (Endress and Matthews 2006) and, given the variation documented here, may inform classifications at lower (inter- and intraspecific) taxonomic levels in Mangifera and other Anacardiaceae.

Staminodes may be either vestigial or functional (Decraene and Smets 2001). Vestigial staminodes are derived from functional stamens, and may be vascularised and morphologically similar to or indistinguishable from pollen-producing stamens, depending on the extent of reduction (Decraene and Smets 2001). In contrast, functional staminodes have particular floral functions (e.g. production of food rewards such as sterile pollen or nectar), and may be derived from sterile stamens by a comparatively simple transition involving the origin of a vascular connection (Decraene and Smets 2001).

In the current study, we described nectary pores and nectar drops on the surface of staminode heads in mango. Several insect-pollinated genera of flowering plants have nectaries which develop on modified stamens and staminodes, which are considered a primitive manifestation of nectaria cauda (Smets 1986; Weryszko-Chmielewska et al. 2003; Weryszko-Chmielewska and Sulborska 2011). In mango staminodes, nectariferous tissue is usually fed by a single vascular bundle surrounded by multi-layered parenchyma and a single-layered epidermis at the centre of the nectar (Muniraja et al. 2018). Muniraja et al. (2018) provide additional anatomical details of the vasculature bundle of staminodes in mango. Although the presence of vascularisation alone does not support M. indica staminodes as functional, pronounced morphological differentiation (compare Plate 1 and 2), the production of nectar and its secretion from pores or stomata (Plate 2, figures 5 and 6), and the presence of vascularisation in staminodes and staminodal nectaries (Muniraja et al. 2018) all support a biological function for staminodes in mango (Decraene and Smets 2001). Studies of pollination/pollinator reward and comparative studies of stamen and staminode vascular anatomy may provide additional insight into the origin and function of staminodes in mango.

Anthers of male and hermaphroditic flowers produced an average of 536 and 510 pollen grains, respectively (Table 1). Previous studies in mango report an average of 400 to 800 pollen grains per anther, and decreased pollen production in male compared to hermaphroditic flowers, depending on the cultivar (Gehrke-Velez et al. 2011). Pollen production is a function of male reproductive fitness and is a key parameter in plant–pollinator interactions (Costa and Yang 2009). Although pollen production from staminodes has not been observed in M. indica, differences in pollen production between anthers of male and hermaphroditic flowers may be useful in assessing male fertility in other Anacardiaceae (Wunnachit et al. 1992; Mert and Soylu 2006; Ramirez and Davenport 2016), where male pollen appears to be specialised for fertilisation and fruit set, and hemaphrodite pollen may serve as an attractant (Wunnachit et al. 1992).

Pollen apertures are the reduced or altered part of the pollen wall where pollen tubes emerge upon grain germination. Apertures vary in shape, number, orientation, and location between angiosperm taxa (Furness et al. 2004), with eudicots usually producing tricolpate (three apertures) pollen, monocots monocolpate (one aperture) pollen, and basal angiosperms pollen with two or more apertures (discussed in APG II 2003; Furness et al. 2004; Pell et al. 2010). Lora and Hormaza (2018) described mango pollen as tricolpate at anther dehiscence. Consistent with the findings of Ramirez and Davenport (2016), the M. indica pollen described herein was tricolporate, spherical in shape with pitted walls, and two-celled at dispersal (see Plate 3). In contrast to other Anacardiaceae (Pradeep 2014), exine ornamentation was reticulate perforate (Plate 3, figures 2–4).

Plate 1.

Scanning electron micrograph of mature anthers: 1. Abaxial side of a pre-dehiscent anther. Scale bar: 100 µm. 2. Irregular-shaped groove and stomata (arrows) on the surface of the anther. Scale bar: 20 µm. 3. Development of longitudinal slit (ls) (arrows) on the anther. Scale bar: 100 µm. 4. Side view of a dehisced anther (arrows) with residual pollen grains (po). Scale bar: 100 µm.

Pollen grains of male and hermaphroditic flowers reported here averaged 26.5 µm and 29.3 µm in diameter, respectively, values which fall within the size range reported for angiosperms (Erdtman 1952), Anacardiaceae, and Mangifera indica (Jayarajan et al. 2016). Furthermore, and in contrast to other mango varieties, the pollen of hermaphroditic flowers in Mangifera indica L. var. Beneshan was slightly smaller than that of male flowers (Table 1; Li 1992), although the somewhat rounder shape reported here appears typical for hermaphrodite pollen in Mangifera indica (Ramirez and Davenport 2016).

In this study, the mean pollen viabilities of hermaphroditic and male flowers were 50.1% and 40.4%, respectively. These findings are consistent with those of Gehrke-Velez et al. (2011), who reported higher viabilities in hermaphroditic flowers compared to male flowers in Mangifera indica L. cv. Ataulfo. However, the percentages of pollen viability documented in the current study are lower than those reported for other mango varieties such as ‘Kent' (23–96%; Dag et al. 2000) and ‘Sensation', ‘Tommy Atkins’, and ‘Janardhan Pasand’ (83.4–88.2%; Dutta et al. 2013). A number of variables not rigorously controlled for in this study are known to influence pollen viability in Mangifera and may account for the relatively low viabilities reported here. These include decreased temperature at anthesis (Ramirez and Davenport 2016) and increased time between pollen collection and analysis (de Wet et al. 1989), both of which negatively impact viability.

Plate 2.

Scanning electron micrograph of staminodes of Mangifera indica L.: 1. Capitate staminode with a filament from a male flower (arrows). Scale bar: 30 µm. 2. Staminode with a terminal hook (arrow). Scale bar: 30 µm. 3. A staminode with irregular cells on the surface and parallel ornamentation (arrows). Scale bar: 10 µm. 4. Stomata (sm) (arrows) on the surface of the staminode. Scale bar: 20 µm. 5. The presence of stomata (arrows) and the secretion (sc) (arrow) of nectar from the stomata (arrows). Scale bar: 10 µm. 6. Expanded view of nectar drops (nb) (arrows). Scale bar: 10 µm.

Plate 3.

Scanning electron micrographs of mature pollen grains with different proximal faces: 1. A group of pollen grains from hermaphrodite flowers. Scale bar: 10 µm. 2. Tricolpate hermaphrodite pollen grain in polar view (arrows). Scale bar: 2 µm. 3. Tricolpate male pollen grain in equatorial view (arrows). Scale bar: 2 µm. 4. Pollen exine with psilate perforate ornamentation (arrows). Scale bar: 2 µm.

5. Conclusions

In this study, we described numerous ultrastructural features of potential taxonomic utility in mango (M. indica var. Beneshan). These include differences in anther and staminode size within and between hermaphroditic and male flowers, differences in anther size between flower types, and numerous staminode characteristics that varied between and sometimes within flower types, including the presence of distinct ridges (Plate 2, figure 1), variability in cell shape and size (Plate 2, figure 2), the presence of hook-like outgrowths (Plate 2, figure 3), and the occurrence of nectar-secreting stomata on staminode heads (Plate 2, figures 4–6). Pollen of M. indica var. Beneshan is morphologically similar to that of the other members of the subfamily Anacardioideae, including similarities in size, shape, and number of apertures. However, in mango exine ornamentation is reticulate perforate, whereas it is reticulate or reticulate striate in other members of Anacardioideae (Pradeep 2014). Pollen viability studies are of great importance in mango breeding programmes and commercial fruit production. We report moderate (40–50%) pollen viabilities in M. indica var. Beneshan compared to other varieties. However, mango pollen is highly sensitive to desiccation and there is rapid loss of moisture when pollen is exposed to higher temperatures (Dutta et al. 2013). Moreover, decreased temperatures at anthesis negatively impact mango pollen viability, as does the overall time between pollen collection and viability analysis (Ramirez and Davenport 2016). Heslop-Harrison et al. (1984) suggested correlation studies on pollen viability with FDA and in vitro germination of mature pollen to reduce erroneous viability estimates, and such studies are needed in M. indica var. Beneshan to corroborate the relatively low viabilities reported here. This research provides new ultrastructural characters potentially useful in future taxonomic studies of Mangifera. Results presented here may also be useful in pollination studies, and in the improvement of mango breeding programmes and commercial fruit production.

Plate 4.

Photomicrographs related to pollen size, pollen development, and pollen viability: 1. Pollen grain of a hermaphrodite flower showing the three-aperture (ap) stage, stained with aceto-carmine (arrows). Scale bar: 10 µm. (in 100×). 2. Just-released pollen grains with three apertures (ap) (arrows), (at 100×). Scale bar: 10 µm. 3. Viable pollen grains (vpo) stained with FDA (arrows) (at 40×). 4. Non-viable pollen grains (nvpo) Differential Interference Contrast (DIC) stained with fluorescein diacetate (FDA) (arrows) (at 40×).