A meta‐analysis of responses in floral traits and flower–visitor interactions to water deficit

Kuppler, Jonas; Kotowska, Martyna M.

doi:10.1111/gcb.15621

Cited by 59 publications

(70 citation statements)

References 131 publications

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“…Unlike our findings related to nutrient availability, our results concerning the limited effects of water on both scent and flower number contrast, at least in part, with previous studies, which have found that water availability can have varying consequences for scent emission rate and composition, including no effect at all for some species or compounds (Burkle & Runyon, 2016; Campbell et al., 2018; Glenny et al., 2018; Rering et al., 2020), and that water limitation generally decreases overall flower number (Kuppler & Kotowska, 2021; Kuppler et al., 2021). These previous studies on the effects of water on scent captured the effects of relatively short‐term changes in soil water conditions.…”

Section: Discussioncontrasting

confidence: 68%

“…(2019) took measurements at multiple time points and found that plants' responses to drought changed over time; our study setup would not have picked up such gradual changes. Overall, our results suggest that, at least at the levels experienced by A. alpina in our study, drought may have no effect on floral display (including both scent and visual characteristics), perhaps not causing the general decrease in pollinator visitation observed in response to drought in other studies (Kuppler & Kotowska, 2021; Kuppler et al., 2021).…”

Section: Discussioncontrasting

confidence: 39%

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Phenotypic plasticity in floral scent in response to nutrient, but not water, availability in the perennial plant Arabis alpina

2021

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Floral scent is an important mediator of plant–pollinator interactions. Multiple recent studies report ample intraspecific scent variation among populations and individuals. Yet, few studies have estimated effects of phenotypic plasticity on floral scent in response to differing environmental factors. In this study, we investigated the effects of nutrient and water availability on floral scent in self‐compatible and self‐incompatible populations of the perennial herb Arabis alpina. We subjected greenhouse grown plants to different nutrient and water treatments in a crossed design, examined the effects on floral scent emission rate and composition, compared the level of plasticity to that of other plant traits, and conducted hand‐pollinations of nutrient‐limited individuals to test for a potential allocation cost of scent production. For both self‐compatible and self‐incompatible populations, the per‐flower scent emission rate was 1.2–4 times higher when nutrients were abundant, but this effect explained little variation in scent emission rate and was limited compared to plasticity in flower number. There was no effect of water treatment on scent emission. Additionally, neither treatment had an effect on the composition of the floral scent, and there was no detectable trade‐off between scent and seed production that would imply a cost of floral scent production. Overall, while per‐flower floral scent emission displayed limited phenotypic plasticity in response to nutrient conditions, the total amount of scent emitted by plants may increase more strongly at higher nutrient availabilities due to an increase in flower production. Therefore, our results suggest that fitness benefits due to increased scent emission rates under favourable nutrient conditions might depend on the extent to which floral scent serves as a long‐ or short‐distance pollinator attractant for the focal plant species. A free Plain Language Summary can be found within the Supporting Information of this article.

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Section: Discussioncontrasting

confidence: 68%

Section: Discussioncontrasting

confidence: 39%

Phenotypic plasticity in floral scent in response to nutrient, but not water, availability in the perennial plant Arabis alpina

2021

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“…In this study, plants were irrigated sufficiently to avoid drought stress. Under drought stress, the results may have been different because nectar production generally decreases during periods of drought, but the magnitude of this effect can vary across plant species (Carroll et al, 2001;Gallagher and Campbell 2021;Kuppler and Kotowska 2021;Rering et al, 2020). Our results further highlight the need to sample nectar across seasons as nectar production, and relative differences across taxa, can vary over time.…”

Section: Discussionmentioning

confidence: 80%

Evaluation of Native and Nonnative Ornamentals as Pollinator Plants in Florida: II. Floral Resource Value

Kalaman

Wilson

Mallinger

et al. 2022

horts

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Consumer demand for novel, visually attractive ornamentals has often overshadowed the functional value plants may provide for flower-visiting insects. As native and nonnative species are hybridized for form, color, flowering, and disease resistance, it is important to assess whether some of these alterations influence plant nutrient quality for foraging insect pollinators. A study was conducted to ascertain the resource value of ornamental cultivars compared with their native congeners. The nectar volume and pollen quantity, viability, and protein content of 10 species of popular herbaceous flowering plants, commonly advertised as pollinator-friendly, were evaluated in northcentral Florida. Each genus encompassed a native and nonnative species, apart from pentas. Native species included blanket flower (Gaillardia pulchella), lanceleaf coreopsis (Coreopsis lanceolata), pineland lantana (Lantana depressa), and scarlet sage (Salvia coccinea). Nonnative species included Barbican™ yellow-red ring blanket flower (Gaillardia aristata ‘Gaiz005’), Bloomify™ rose lantana (Lantana camara ‘UF-1011-2’), mysty salvia (Salvia longispicata × farinacea ‘Balsalmysty’), Lucky Star® dark red pentas (Pentas lanceolata ‘PAS1231189’), ruby glow pentas (Pentas lanceolata ‘Ruby glow’) and UpTick™ Gold & Bronze coreopsis (Coreopsis × ‘Baluptgonz’). Floral rewards differed significantly across species. The native scarlet sage exhibited the largest nectar volume per flower in the summer (2.13 ± 0.17 µL), followed by the nonnative mysty salvia (1.26 ± 0.17 µL). In the fall, ruby glow pentas exhibited the largest nectar volume per flower (1.09 ± 0.17 µL) compared with all other ornamentals. The composite flowers of the native and nonnative blanket flower and coreopsis species had the lowest nectar volume per flower regardless of sampling date. Likewise, ruby glow pentas displayed the highest quantity of pollen grains (96.29 ± 0.12) per sample, followed by Lucky star pentas (52.33 ± 0.12), and Barbican blanket flower (50.98 ± 0.12). Pollen viability was similarly high (92% to 98%) among all species, apart from Bloomify rose lantana (20%) and pineland lantana (48%). Pollen protein content was highest in Uptick coreopsis (11.378 ± 1.860 μg/mg dry weight) and Lucky star pentas (10.656 ± 3.726 μg/mg dry weight), followed by lanceleaf coreopsis (7.918 ± 1.793 μg/mg dry weight). These results largely showed that the nonnative ornamentals selected provided resource-rich floral rewards, comparable to native congeners. Still, care should be taken in making similar assessments of other modern floral types.

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“…The enhancement of temperature and humidity have a significant effect on the amounts of floral scent components, especially FVTs from the O. fragrans cultivars [44], P. axillaris [161], J. auriculatum [32], Lilium 'Siberia' [162] and seven common Mediterranean species [163]. As a result, the attractive characteristics of the floral fragrances are diminished due to the changed compositions of FVTs and the release rates of particular FVTs, such as (E)-β-ocimene, (E,E)-α-farnesene and αand β-pinene [160,[164][165][166].…”

Section: Ambient Temperature and Relative Humiditymentioning

confidence: 99%

An Update on the Function, Biosynthesis and Regulation of Floral Volatile Terpenoids

Qiao

Shi

et al. 2021

Horticulturae

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Floral volatile terpenoids (FVTs) belong to a group of volatile organic compounds (VOC) that play important roles in attracting pollinators, defending against pathogens and parasites and serving as signals associated with biotic and abiotic stress responses. Although research on FVTs has been increasing, a systematic generalization is lacking. Among flowering plants used mainly for ornamental purposes, a systematic study on the production of FVTs in flowers with characteristic aromas is still limited. This paper reviews the biological functions and biosynthesis of FVTs, which may contribute a foundational aspect for future research. We highlight regulatory mechanisms that control the production of FVTs in ornamental flowers and the intersection of biosynthetic pathways that produce flower fragrance and color. Additionally, we summarize the opportunities and challenges facing FVT research in the whole genome and -omics eras and the possible research directions that will provide a foundation for further innovation and utilization of flowering ornamental plants and their germplasm resources.

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A meta‐analysis of responses in floral traits and flower–visitor interactions to water deficit

Cited by 59 publications

References 131 publications

Phenotypic plasticity in floral scent in response to nutrient, but not water, availability in the perennial plant Arabis alpina

Phenotypic plasticity in floral scent in response to nutrient, but not water, availability in the perennial plant Arabis alpina

Evaluation of Native and Nonnative Ornamentals as Pollinator Plants in Florida: II. Floral Resource Value

An Update on the Function, Biosynthesis and Regulation of Floral Volatile Terpenoids

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