Floral nectary and osmophore of Epipactis helleborine (L.) Crantz (Orchidaceae)

Kowalkowska, Agnieszka K.; Pawłowicz, Michalina; Guzanek, P; Krawczyńska, Agnieszka

doi:10.1007/s00709-018-1274-5

Cited by 20 publications

(19 citation statements)

References 53 publications

(76 reference statements)

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“…The extensive system of mitochondrial inner membranes, the endoplasmic reticulum with varied arrangement of tubules and the numerous transporting vesicles observed near the plasmalemma in the present study suggest granulocrine nectar secretion. A similar mode of nectar secretion is characteristic for many species of various genera (Chwil and Chwil 2012; Ojeda et al 2014; Kowalkowska et al 2018). The floral nectaries exhibited expanded ER cisterns and large vesicles associated mainly with the cis -side of dictyosomes.…”

Section: Discussionmentioning

confidence: 69%

“…The secretion was transported inside the vesicular structures and, next, through the fusion of vesicles with the plasmalemma, the excretion was accumulated in the subcuticular space. The irregular outline of the plasmalemma with numerous vesicles determined the granulocrine secretion of nectar into the periplasmic space and then onto the outer surface (Chwil and Chwil 2012; Kowalkowska et al 2012, 2015, 2018).…”

Section: Discussionmentioning

confidence: 99%

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Comparative studies on structure of the floral nectaries and the abundance of nectar production of Prunus laurocerasus L.

2019

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There is very scanty information concerning the floral nectary structure and nectar secretion in Prunus laurocerasus L. Therefore, the aim of the study was to determine the micromorphology, anatomy and ultrastructure of nectaries; the abundance of nectar production; and the quantitative and qualitative composition of sugars contained in the nectar of two P. laurocerasus cultivars: ‘Schipkaensis’ and ‘Zabeliana’. The nectary structure was studied using light, fluorescence, scanning and transmission electron microscopy techniques. The nectar sugars were analysed with HPLC. The ‘Schipkaensis’ had longer inflorescences with a larger number of flowers and a longer perianth than ‘Zabeliana’. The micromorphological structure of the nectaries in ‘Schipkaensis’ exhibited denser (approx. 39%) and larger (approx. 50%) stomata and thicker (approx. 13%) cuticular striae forming wider bands (approx. 26%) than in ‘Zabeliana’. The results provide new data on the micromorphology, anatomy and ultrastructure of these floral nectaries. Nectary cuticle ornamentation as well as the size, type and density of stomata and stomatal complex topography can have a diagnostic value in Prunus. The nectar sugar weight indicates a significant apicultural value of the cherry laurel, especially in the case of ‘Schipkaensis’. Cherry laurel is an entomophilous species recommended for cultivation in nectariferous zones and insect pollinator refuges; however, climatic conditions eliminating the invasiveness of these plants should be considered.

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Section: Discussionmentioning

confidence: 69%

Section: Discussionmentioning

confidence: 99%

Comparative studies on structure of the floral nectaries and the abundance of nectar production of Prunus laurocerasus L.

2019

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“…Similar types of plastids were present in nectary cells in representatives of other families, e.g. Orchidaceae (De Melo et al 2010;Kowalkowska et al 2018) and Sapinadaceae (Weryszko-Chmielewska and Chwil 2017). The large amounts of smooth and rough ER profiles visible in the glandular parenchyma may have been involved in the synthesis of lipid and protein substances, respectively, and/or mediated the production and transport of nectar.…”

Section: Flower and Nectary Microstructurementioning

confidence: 62%

Taxonomic traits in the microstructure of flowers of parasitic Orobanche picridis with particular emphasis on secretory structures

Konarska

Chmielewski

2019

Protoplasma

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Orobanche picridis is an obligate root parasite devoid of chlorophyll in aboveground organs, which infects various Picris species. Given the high level of phenotypic variability of the species, the considerable limitation of the number of taxonomically relevant traits (mainly in terms of generative elements), and the low morphological variation between species, Orobanche is regarded as one of the taxonomically most problematic genera. This study aimed to analyse the taxonomic traits of O. picridis flowers with the use of stereoscopic and bright-field microscopy as well as fluorescence, scanning, and transmission electron microscopy. The micromorphology of sepals, petals, stamens, and pistils was described. For the first time, the anatomy of parasitic Orobanche nectaries and the ultrastructure of nectaries and glandular trichomes were presented. Special attention was paid to the distribution and types of glandular and non-glandular trichomes as well as the types of metabolites contained in these structures. It was demonstrated that the nectary gland was located at the base of the gynoecium and nectar was secreted through modified nectarostomata. The secretory parenchyma cells contained nuclei, large amyloplasts with starch granules, mitochondria, and high content of endoplasmic reticulum profiles. Nectar was transported via symplastic and apoplastic routes. The results of histochemical assays and fluorescence tests revealed the presence of four groups of metabolites, i.e. polyphenols (tannins, flavonoids), lipids (acidic and neutral lipids, essential oil, sesquiterpenes, steroids), polysaccharides (acidic and neutral polysaccharides), and alkaloids, in the trichomes located on perianth elements and stamens.

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“…The nectariferous parenchyma is composed of small isodiametric cells with densely-staining cytoplasm, and closely packed papillae glands, which are composed of a single basal cell, variable number of stalk cells, and terminal head cells protruding from the epidermis (Bernardello et al, 2007; Eleftheriou and Hall, 1983a; Fahn, 1979; Findlay et al, 1971b; Kronestedt et al, 1986; Lattar et al, 2018; Sawidis et al, 1987; Wergin et al, 1975). Large phenolic ‘dense’ bodies and calcium oxalate crystals form in all four nectaries and based on their postulated functionality in nectaries of other plant taxa, such as Glycine , Linaria , Epipactis , Heliocarpus , Luehea , Ekebergia , and Anacardium , they may confer protection from herbivory (Horner et al, 2003; Jachuła et al, 2018; Kowalkowska et al, 2018; Lattar et al, 2018; Tilney et al, 2018; Tölke et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

“…During active nectar secretion, the cuticle of the papillae head cells separates from the cell wall and the newly formed subcuticular space, which fills with nectar; microchannels or fractures develop in the cuticle to facilitate the release of nectar from the nectary. This phenomenon commonly occurs in the trichomatic nectaries of a variety of other species, included within Malvaceae (Findlay et al, 1971b; Haratym and Weryszko-Chmielewska, 2017; Kowalkowska et al, 2018; Kronestedt et al, 1986; Lattar et al, 2018; Plachno et al, 2018; Sawidis et al, 1987). Based on previous observations of Abutilon hydridum floral nectary papillae, the cuticular channels may function as valves, releasing discrete droplets of nectar once hydrostatic pressure exceeds a threshold (Findlay et al, 1971b).…”

Section: Discussionmentioning

confidence: 99%

Systems analyses of key metabolic modules of floral and extrafloral nectaries of cotton

Chatt

Mahalim

Mohd-Fadzil

et al. 2019

Preprint

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23United States 24 25 Author contributions 26 ECC, CJC, and BJN conceived and planned the study. Sample collection, microscopy, and 27 metabolomic analyses were conducted by ECC, SNM, and NAMF. Additional contributions 28 for microscopic analyses were provided by HTH. RNA preparation was completed by PMK, 29 RR, and CJC. MH processed all RNAseq data and conducted informatics analyses in 30 conjunction with ECC. ECC and BJN wrote the manuscript with feedback from all 31 coauthors. 33One sentence summary 34 The eccrine-based model of nectar synthesis and secretion is conserved in both trichomatic 35 and extrafloral nectaries determined by a system-based comparison of cotton (Gossypium 36 hirsutum) nectaries. 37 Abstract 47 Nectar is a primary reward mediating plant-animal mutualisms to improve plant fitness and 48 reproductive success. In Gossypium hirsutum (cotton), four distinct trichomatic nectaries 49 develop, one floral and three extrafloral. The secreted floral and extrafloral nectars serve 50 different purposes, with the floral nectar attracting bees to promote pollination and the 51 extrafloral nectar attracting predatory insects as a means of indirect resistance from herbivores. 52 Cotton therefore provides an ideal system to contrast mechanisms of nectar production and 53 nectar composition between floral and extrafloral nectaries. Here, we report the transcriptome, 54 ultrastructure, and metabolite spatial distribution using mass spectrometric imaging of the four 55 cotton nectary types throughout development. Additionally, the secreted nectar metabolomes 56 were defined and were jointly composed of 197 analytes, 60 of which were identified. 57 Integration of theses datasets support the coordination of merocrine-based and eccrine-based 58 models of nectar synthesis. The nectary ultrastructure supports the merocrine-based model due 59 to the abundance of rough endoplasmic reticulum positioned parallel to the cell walls and 60 profusion of vesicles fusing to the plasma membranes. The eccrine-based model which consist 61 of a progression from starch synthesis to starch degradation and to sucrose biosynthesis was 62 supported by gene expression data. This demonstrates conservation of the eccrine-based model 63 for the first time in both trichomatic and extrafloral nectaries. Lastly, nectary gene expression 64 data provided evidence to support de novo synthesis of amino acids detected in the secreted 65 nectars.66 67 68 69 130 synthesis to assess for the first time whether this model is conserved among trichomatic and 131 extrafloral nectaries. 132 Results 133 Domesticated Upland cotton, G. hirsutum (TM-1), develops four types of nectaries, 134 three are extrafloral and one is floral, and all consist of multicellular glandular trichomes, 135 specifically called papillae. The three extrafloral nectary types, foliar, bracteal, and 136 circumbracteal, are subcategorized as vegetative or reproductive. The vegetative foliar nectary 137is located on the abaxial surface of the leaf midrib ( Fig. 1A; Fig...

show abstract

Floral nectary and osmophore of Epipactis helleborine (L.) Crantz (Orchidaceae)

Cited by 20 publications

References 53 publications

Comparative studies on structure of the floral nectaries and the abundance of nectar production of Prunus laurocerasus L.

Comparative studies on structure of the floral nectaries and the abundance of nectar production of Prunus laurocerasus L.

Taxonomic traits in the microstructure of flowers of parasitic Orobanche picridis with particular emphasis on secretory structures

Systems analyses of key metabolic modules of floral and extrafloral nectaries of cotton

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