Functional Ecology of External Secretory Structures in Rivea ornata (Roxb.) Choisy (Convolvulaceae)

Chitchak, Natthaphong; Stewart, Alyssa B.; Traiperm, Paweena

doi:10.3390/plants11152068

Cited by 4 publications

(3 citation statements)

References 113 publications

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“…The histochemical and fluorescence assays showed the presence of lipid compounds (total lipids, acidic, and neutral lipids) and phenolic compounds (total phenols, phenolic acids, and flavonoids) in the tissues and glandular trichomes of the D. moldavica nectary. Various authors also reported the presence of similar groups of metabolites in nectaries of other plant species [ 57 , 58 , 59 , 60 ]. Similar to the present findings, these researchers showed that the metabolites were located in the nectary epidermis and/or parenchyma; next, the compounds penetrated into the secreted nectar.…”

Section: Discussionmentioning

confidence: 87%

Does the Floral Nectary in Dracocephalum moldavica L. Produce Nectar and Essential Oil? Structure and Histochemistry of the Nectary

Konarska

Weryszko-Chmielewska

Dmitruk

et al. 2022

Biology

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Dracocephalum moldavica is an aromatic plant with a lemon scent and versatile use. Its flowers produce large amounts of nectar, which is collected by bees and bumblebees. The aim of the study was to investigate the structure of the floral nectary in this melliferous plant, which has not been analysed to date. The analyses were carried out with the use of light, fluorescence, scanning electron, and transmission electron microscopy, as well as histochemical techniques. The four-lobed nectary with a diameter of 0.9–1.2 mm and a maximum height of 1.2 mm is located at the ovary base; one of its lobes is larger than the others and bears 20–30 nectarostomata and 8–9 glandular trichomes. The histochemical assays revealed the presence of essential oil and phenolic compounds in the nectary tissues and in glandular trichomes. The nectary tissues are supplied by xylem- and phloem-containing vascular bundles. The nectariferous parenchyma cells have numerous mitochondria, plastids, ribosomes, dictyosomes, ER profiles, vesicles, thin cell walls, and plasmodesmata. Starch grains are present only in the tissues of nectaries in floral buds. The study showed high metabolic activity of D. moldavica nectary glands, i.e., production of not only nectar but also essential oil, which may increase the attractiveness of the flowers to pollinators, inhibit the growth of fungal and bacterial pathogens, and limit pest foraging.

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Section: Discussionmentioning

confidence: 87%

Does the Floral Nectary in Dracocephalum moldavica L. Produce Nectar and Essential Oil? Structure and Histochemistry of the Nectary

Konarska

Weryszko-Chmielewska

Dmitruk

et al. 2022

Biology

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“…Our pollinator observations indicate that both A. versicolor and A. mekongensis are pollinated by carpenter bees. Previous studies have generally reported that Convolvulaceae species are mainly pollinated by bees ( Galetto and Bernadello 2004 ; Maimoni-Rodella and Yanagizawa 2007 ; Pick and Schlindwein 2011 ; Hassa et al 2023 ) or by bees and butterflies ( Hassa et al 2020 ; Jirabanjongjit et al 2021 ) or by hawkmoths ( Willmott and Burquez 1996 ; McMullen 2009 ; Chitchak et al 2022 ). Pollination studies of Argyreia are scarce compared to sister genera such Ipomoea , but Chitchak et al (2018) did report that Xylocopa nasalis visits Argyreia gyrobracteata and receives pollen on its head.…”

Section: Discussionmentioning

confidence: 99%

Near extinct Argyreia versicolor and rare Argyreia mekongensis are dependent on carpenter bee pollinators

Jirabanjongjit,

Traiperm,

Rattanamanee

et al. 2024

AoB PLANTS

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Argyreia versicolor (Kerr) Staples & Traiperm and A. mekongensis Gagnep. & Courchet are extremely rare plant species. The former had not been seen for nearly 100 years, until two individuals were found in Thailand in 2018, and only a handful of populations are known for the latter. The aims of this study were to examine the breeding systems of A. versicolor and A. mekongensis using pollination experiments and to determine their potential pollinators via floral observations. Our controlled pollination experiments uncovered the self-incompatibility of both species. Pollinator censuses indicated that females of two carpenter bee species, Xylocopa aestuans and X. latipes, were the predominant floral visitors for both Argyreia species. Our observations confirmed a harmonious match between the floral shape of both Argyreia species and the body sizes of these pollinators, ensuring effective pollen transfer and validating their role as putative pollinators. In line with the high frequency of pollinator visits observed, our controlled pollination experiments found no evidence of pollen limitation under field conditions. The findings of this study hold significance for the conservation of these endangered species, yet the situation is dire for A. versicolor, with one of the two individuals under study recently lost. Hence, it is crucial to intensify monitoring efforts for the species, aiming to identify additional individuals for potential inclusion in an ex-situ conservation program. Simultaneously, safeguarding the habitat of these plant species and their pollinators will be critical.

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“…Extrafloral nectaries are also considered as storage organs for secondary metabolites. Cassava, tapioca, passiflora, cotton, cashew nut trees, and several members of the Rosaceae have been reported to emit secondary metabolites from extra floral nectaries that aid in luring predators of various pest species [ 108 , 109 ].…”

Section: Storage Of Secondary Metabolitesmentioning

confidence: 99%

Plant Secondary Metabolites: The Weapons for Biotic Stress Management

Al-Khayri,

Rashmi,

Toppo

et al. 2023

Metabolites

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The rise in global temperature also favors the multiplication of pests and pathogens, which calls into question global food security. Plants have developed special coping mechanisms since they are sessile and lack an immune system. These mechanisms use a variety of secondary metabolites as weapons to avoid obstacles, adapt to their changing environment, and survive in less-than-ideal circumstances. Plant secondary metabolites include phenolic compounds, alkaloids, glycosides, and terpenoids, which are stored in specialized structures such as latex, trichomes, resin ducts, etc. Secondary metabolites help the plants to be safe from biotic stressors, either by repelling them or attracting their enemies, or exerting toxic effects on them. Modern omics technologies enable the elucidation of the structural and functional properties of these metabolites along with their biosynthesis. A better understanding of the enzymatic regulations and molecular mechanisms aids in the exploitation of secondary metabolites in modern pest management approaches such as biopesticides and integrated pest management. The current review provides an overview of the major plant secondary metabolites that play significant roles in enhancing biotic stress tolerance. It examines their involvement in both indirect and direct defense mechanisms, as well as their storage within plant tissues. Additionally, this review explores the importance of metabolomics approaches in elucidating the significance of secondary metabolites in biotic stress tolerance. The application of metabolic engineering in breeding for biotic stress resistance is discussed, along with the exploitation of secondary metabolites for sustainable pest management.

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Functional Ecology of External Secretory Structures in Rivea ornata (Roxb.) Choisy (Convolvulaceae)

Cited by 4 publications

References 113 publications

Does the Floral Nectary in Dracocephalum moldavica L. Produce Nectar and Essential Oil? Structure and Histochemistry of the Nectary

Does the Floral Nectary in Dracocephalum moldavica L. Produce Nectar and Essential Oil? Structure and Histochemistry of the Nectary

Near extinct Argyreia versicolor and rare Argyreia mekongensis are dependent on carpenter bee pollinators

Plant Secondary Metabolites: The Weapons for Biotic Stress Management

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