Land use and pollinator dependency drives global patterns of pollen limitation in the Anthropocene

Bennett, Joanne M.; Steets, Janette A.; Burns, Jean H.; Burkle, Laura A.; Vamosi, Jana C.; Wolowski, Marina; Arceo‐Gómez, Gerardo; Burd, Martin; Durka, Walter; Ellis, Allan G.; Freitas, Leandro; Li, Junmin; Rodger, James G.; Ștefan, Valentin; Ji, Xia; Knight, Tiffany M.; Ashman, Tia Lynn

doi:10.1038/s41467-020-17751-y

Cited by 91 publications

(79 citation statements)

References 45 publications

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“…Previous findings show that land use changes such as agricultural intensification, habitat fragmentation, and urbanization affect pollination service negatively, which might in turn cause pollen limitation in plants (Aguilar et al., 2006; Cunningham, 2000; Knight et al., 2018). A recent meta‐analysis shows that globally, plants in urban habitats are nearly twice as pollen limited as plants that occur in natural environments (Bennett et al., 2020). At our site, there have been little urbanization and agricultural activities, hence limited habitat fragmentation and pesticide use.…”

Section: Discussionmentioning

confidence: 99%

“…Plant mating systems such as autogamy (self‐fertilization) are known to buffer plant species from pollen limitation (Knight et al., 2005). Autogamous plants that are able to fully reproduce even in the absence of visits from animal pollinators are less prone to pollen limitation than plants with outcrossing mating systems (Bennett et al., 2020; Knight et al., 2005). The distributional pattern of autogamous plant mating systems across the globe is likely in response to low pollinator abundances or effectiveness of pollinators at some locations (Grossenbacher et al., 2015; Moeller et al., 2017; Ollerton et al., 2011).…”

Section: Introductionmentioning

confidence: 99%

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Pollinator dependence but no pollen limitation for eight plants occurring north of the Arctic Circle

Koch

Zoller

Bennett

et al. 2020

Ecology and Evolution

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Pollinator dependence but no pollen limitation for eight plants occurring north of the Arctic Circle

Koch

Zoller

Bennett

et al. 2020

Ecology and Evolution

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“… Schemske and Bierzychudek (2001) found a similar effect in Linanthus parryae , in that blue morphs produced more seeds than white morphs in years of low spring precipitation, possibly linked to bee preference. Since important pollinators like bees prefer blue hues, this suggests that in more stressful environments, selection might favor blue floral colors if possible, to provide resilience in the face of resource restrictions as to help attract presumably scarcer bee pollinators, as pollinator limitation is a major factor in plant reproductive success ( Burd, 1994 ; Bennett et al, 2020 ; Giejsztowt et al, 2020 ). However, few studies have considered pollinator perception in such analyses, and below we attempt to synthesize available evidence to bridge the potentially contributing abiotic and biotic factors that might influence flower coloration.…”

Section: Water Availability and Drought Stressmentioning

confidence: 99%

Fragmentary Blue: Resolving the Rarity Paradox in Flower Colors

Dyer

Jentsch²,

Burd³

et al. 2021

Front. Plant Sci.

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Blue is a favored color of many humans. While blue skies and oceans are a common visual experience, this color is less frequently observed in flowers. We first review how blue has been important in human culture, and thus how our perception of blue has likely influenced the way of scientifically evaluating signals produced in nature, including approaches as disparate as Goethe’s Farbenlehre, Linneaus’ plant taxonomy, and current studies of plant-pollinator networks. We discuss the fact that most animals, however, have different vision to humans; for example, bee pollinators have trichromatic vision based on UV-, Blue-, and Green-sensitive photoreceptors with innate preferences for predominantly short-wavelength reflecting colors, including what we perceive as blue. The subsequent evolution of blue flowers may be driven by increased competition for pollinators, both because of a harsher environment (as at high altitude) or from high diversity and density of flowering plants (as in nutrient-rich meadows). The adaptive value of blue flowers should also be reinforced by nutrient richness or other factors, abiotic and biotic, that may reduce extra costs of blue-pigments synthesis. We thus provide new perspectives emphasizing that, while humans view blue as a less frequently evolved color in nature, to understand signaling, it is essential to employ models of biologically relevant observers. By doing so, we conclude that short wavelength reflecting blue flowers are indeed frequent in nature when considering the color vision and preferences of bees.

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“…Pollination is essential for plant reproduction in both natural and agricultural ecosystems [1][2][3] . However, plant reproduction is increasingly limited by the quality or quantity of pollen deposited on the stigmas of owers 4,5 . Roughly 50% of plant species rely on or bene t from cross-pollination for successful reproduction 6,7 .…”

Section: Introductionmentioning

confidence: 99%

“…cross-pollination in almonds increases the oleic to linoleic acid ratio, which has been linked to their cardio-protective effects 17,19 . For most crops, we do not understand to what extent self-v. cross-pollination contribute to the crop at harvest despite plant reproduction being increasingly pollen limited 4,5 . We also do not know how self-v. cross-pollination affect crop quality parameters such as fruit size or nutritional quality.…”

Section: Introductionmentioning

confidence: 99%

SNP Markers Reveal Relationships between Fruit Paternity, Fruit Quality and Distance from a Cross-pollen Source in Persea Americana Orchards

Kämper

Ogbourne

Hawkes

et al. 2020

Preprint

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Plant reproductive output is increasingly pollen limited, and cross-pollination can improve fruit yield, fruit size and nutritional quality of many food crops. However, we rarely understand what proportions of the crop result from self- or cross-pollination, how cross-pollination affects crop quality, and how far pollen is transported by pollinators. Management strategies to improve pollination services are consequently not optimal for many crops.We utilised a series of SNP markers, unique for each cultivar of avocado, to quantify proportions of self- and cross-paternity in fruit of Hass avocado at increasing distances from cross-pollen sources. We assessed whether distance from a cross-pollen source determined the proportions of self-pollinated and cross-pollinated fruit, and evaluated how self- and cross-paternity affected fruit size and nutritional quality.Avocado fruit production resulted from both self- and cross-pollination. Cross-pollination levels decreased with increasing distance from a cross-pollen source, from 63% in the row adjacent to another cultivar to 25% in the middle of a single-cultivar block, suggesting that pollen transport was limited across orchard rows. Limited pollen transport did not affect fruit size or quality in Hass avocados as xenia effects of a Shepard polliniser on size and nutritional quality were minor.

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Land use and pollinator dependency drives global patterns of pollen limitation in the Anthropocene

Cited by 91 publications

References 45 publications

Pollinator dependence but no pollen limitation for eight plants occurring north of the Arctic Circle

Pollinator dependence but no pollen limitation for eight plants occurring north of the Arctic Circle

Fragmentary Blue: Resolving the Rarity Paradox in Flower Colors

SNP Markers Reveal Relationships between Fruit Paternity, Fruit Quality and Distance from a Cross-pollen Source in Persea Americana Orchards

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